Item 1. Business.
Unless the context otherwise requires, all references in this section to “we,” “us,” “our,” or the “Company” refer to the current QuantumScape Corporation and its subsidiaries.
Corporate History and Background
On November 25, 2020 (the “Closing Date”), Kensington, consummated the Business Combination Agreement (the “Business Combination Agreement”) dated September 2, 2020, by and among Kensington, Kensington Merger Sub Corp., a Delaware corporation and wholly owned subsidiary of Kensington (“Merger Sub”), and QuantumScape Battery, Inc., a Delaware corporation (f/k/a QuantumScape Corporation and f/k/a QuantumScape Subsidiary, Inc.) (“Legacy QuantumScape”) formed in May of 2010. Our Class A Common Stock and Public Warrants are listed on NYSE under the symbols “QS” and “QS.WS”, respectively. Our Class B Common Stock is neither listed nor publicly traded.
Pursuant to the terms of the Business Combination Agreement, a business combination between the Company and Legacy QuantumScape was effected through the merger of Merger Sub with and into Legacy QuantumScape, with Legacy QuantumScape surviving as the surviving company and as a wholly-owned subsidiary of Kensington (the “Merger” and, collectively with the other transactions described in the Business Combination Agreement, the “Business Combination”). On the Closing Date, the Company changed its name from Kensington Capital Acquisition Corp. to QuantumScape Corporation.
Overview
QuantumScape is developing next generation battery technology for electric vehicles (“EVs”) and other applications.
We are at the beginning of a forecasted once-in-a-century shift in automotive powertrains, from internal combustion engines to clean EVs. While current battery technology has demonstrated the benefits of EVs, principally in the premium passenger car market, there are fundamental limitations inhibiting widespread adoption of battery technology. As a result, today, approximately 3% of global light-vehicles are electrified. We believe a new battery technology represents the most promising path to enable a mass market shift.
After 30 years of gradual improvements in conventional lithium-ion batteries we believe the market needs a step change in battery technology to make mass market EVs competitive with the fossil fuel alternative.
We have spent the last decade developing a proprietary solid-state battery technology to meet this challenge. We believe that our technology enables a new category of battery that meets the requirements for broader market adoption. The lithium-metal solid-state battery technology that we are developing is being designed to offer greater energy density, longer life, faster charging, and greater safety when compared to today’s conventional lithium-ion batteries.
Over the last eight years we have developed a strong partnership with VGA and certain of its affiliates (together with VGA, “Volkswagen”). Volkswagen is one of the largest car companies in the world and intends to be a leader in EVs. Volkswagen has announced plans to launch more than 70 new EV models and build more than 25 million vehicles on electric platforms by the end of the decade. Over the last eight years Volkswagen has invested and committed to invest, subject, in certain cases, to certain closing conditions that have not yet been satisfied, a total of more than $300 million in us and has established a 50-50 joint venture with us to enable an industrial level of production of our solid-state batteries. As 50-50 partners in the joint venture with Volkswagen, we expect to share equally in the revenue and profit from the joint venture. Over the course of our relationship, Volkswagen has successfully tested multiple generations of certain of our single-layer, laboratory cells at industry-accepted automotive rates of power (power is the rate at which a battery can be charged and discharged). We believe no other lithium-metal battery technology has demonstrated the capability of achieving automotive rates of power with acceptable battery life.
While we expect Volkswagen will be the first to commercialize vehicles using our battery technology, over the next few years as we build our initial pre-pilot manufacturing facility and our 1GWh pilot facility (the “Pilot Facility”), we intend to work closely with other automotive original equipment manufacturers (“OEMs”) to make our solid-state battery cells widely available over time. As part of our joint venture agreement we have agreed that the Pilot Facility will be the first commercial-scale facility to manufacture our battery technology for automotive applications, but, subject to the other terms of the joint venture arrangements, we are not limited from working in parallel with other automotive OEMs, or other non-automotive companies, to commercialize our technology. We recently have announced our plans to expand our manufacturing capability with the addition of a pre-pilot line facility in San Jose, CA (“QS-0”). QS-0 is intended to have a continuous flow, high automation line capable of building over 100,000 engineering cell samples per year. We expect to secure a long-term lease for QS-0 in the second half of this year and for QS-0 to be producing cells by 2023.
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Our development uses earth-abundant materials and processes suitable for high volume production. Our processes use tools which are already used at scale in the battery or ceramics industries. Outside of the separator, our battery is being designed to use many of the materials and processes that are standard across today’s battery manufacturers. As a result, we expect to benefit from the projected industry-wide cost declines for these materials that result from process improvements and economies of scale. We believe that the manufacturing of our solid-state battery cells provides us with a structural cost advantage because our battery cells are manufactured without an anode.
There are government regulations pertaining to battery safety, transportation of batteries, use of batteries in cars, factory safety, and disposal of hazardous materials. We will ultimately have to comply with these regulations to sell our batteries into the market. The license and sale of our batteries abroad is likely to be subject to export controls in the future.
Our investor relations website is located at https://ir.quantumscape.com and our Company Twitter account is located at https://twitter.com/QuantumScapeCo. We use our investor relations website and our Company Twitter account to post important information for investors, including news releases, analyst presentations, and supplemental financial information, and as a means of disclosing material non-public information and for complying with our disclosure obligations under Regulation FD. Accordingly, investors should monitor our investor relations website and our Company Twitter account, in addition to following press releases, filings with the Securities and Exchange Commission (the “SEC”) and public conference calls and webcasts. We also make available, free of charge, on our investor relations website under “Financials—SEC Filings,” our Annual Reports on Form 10-K, Quarterly Reports on Form 10-Q, Current Reports on Form 8-K and amendments to these reports as soon as reasonably practicable after electronically filing or furnishing those reports to the SEC.
Industry Background
Shift to EVs
We believe that evolving consumer preferences coupled with growing government incentives and regulations are driving a once-in-a-century shift to EVs.
Countries around the world are promoting EVs. The dependence on gasoline-powered internal combustion engine (“ICE”) vehicles has heightened environmental concerns, created reliance among industrialized and developing nations on large oil imports, and exposed consumers to unstable fuel prices and health concerns related to heightened emissions. Many national and regional regulatory bodies have adopted legislation to incentivize or require a shift to lower-emission and zero-emission vehicles. For example, countries such as the United Kingdom, the Netherlands, Sweden, Germany, and France have announced intentions to either increase applicable environmental targets or outright ban the sale of new ICE vehicles in the next two decades. More recently, California passed regulations requiring half of trucks sold in the state to be zero-emissions by 2035 and 100% by 2045. This global push to transition from ICE vehicles, aided by favorable government incentives and regulations, is accelerating the growth in lower- and zero-emission vehicle markets.
Furthermore, consumers are increasingly considering EVs for a variety of reasons including better performance, growing EV charging infrastructure, significantly lighter environmental impact, and lower maintenance and operating costs. Automakers such as Tesla, Inc. have demonstrated that premium EVs can deliver a compelling alternative to fossil fuels. As EVs become more competitive and more affordable, we believe that they will continue to take market share from ICE vehicles. We believe that this shift will occur across vehicle types and market segments. However, some of the inherent limitations of lithium-ion battery technology remain an impediment to meaningful improvements in EV competitiveness and cost.
Current Battery Technology Will Not Meet the Requirements for Broad Adoption of EVs
Despite the significant progress in the shift to EVs, the market remains dominated by ICE vehicles. According to the International Energy Association, approximately 3% of light vehicles are EVs. For EVs to be adopted at scale across market segments batteries need to improve. In particular, we believe there are five key requirements to drive broad adoption of EVs:
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Battery capacity (energy density). EVs need to be able to drive over 300 miles on a single charge to achieve broad market adoption. The volume required for conventional lithium-ion battery technology limits the range of many EVs. Higher energy density will enable automotive OEMs to increase battery pack energy without increasing the size and weight of the vehicle’s battery pack.
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Fast charging capability. EV batteries need to be fast-charging to replicate the speed and ease with which a gasoline car can be refueled. We believe this objective is achieved with the ability to charge to at least 80% capacity in under 15 minutes, without materially degrading battery life.
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Safety (nonflammable). EV batteries need to replace as many of the flammable components in the battery as possible with non-flammable equivalents to reduce the extent of damage caused by a fire. With current batteries, many abuse conditions, including malfunctions that can result in overcharges and battery damage from accidents, can result in fires.
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Cost. Mass market adoption of EVs requires a battery that is capable of delivering long range while remaining cost competitive with a vehicle price point of around $30,000.
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Battery life. Batteries need to be usable for the life of the vehicle, typically 12 years or 150,000 miles. If the battery fades prematurely, EVs will not be an economically practical alternative.
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Since these requirements have complex interlinkages, most manufacturers of conventional lithium-ion batteries used in today’s cars are forced to make trade-offs. For example, conventional batteries can be fast-charged, but at the cost of significantly limiting their battery life.
We believe that a battery technology that can meet these requirements will enable an EV solution that is much more broadly competitive with internal combustion engines. With more than 90 million ICE vehicles produced in 2019 across the auto industry, there is significant untapped demand for a battery that meets these goals – a potential market opportunity in excess of $450 billion annually.
Limitations of Conventional Lithium-ion Battery Technologies
The last significant development in battery technology was the commercialization of lithium-ion batteries in the early 1990s which created a new class of batteries with higher energy density. Lithium-ion batteries have enabled a new generation of mobile electronics, efficient renewable energy storage, and the start of the transition to electrified mobility.
Since the 1990s, conventional lithium-ion batteries have seen a gradual improvement in energy density. Most increases in cell energy density have come from improved cell design and incremental improvements in cathode and anode technology. However, there is no Moore’s law in batteries – it has taken conventional lithium-ion batteries at least 10 years to double in energy density and it has been approximately 30 years since the introduction of a major new chemistry. As the industry approaches the theoretical limit of achievable energy density for lithium-ion batteries involving carbon, we believe a new architecture is required to deliver meaningful gains in energy density.
Batteries have a cathode (the positive electrode), an anode (the negative electrode), a separator which prevents contact between the anode and cathode, and an electrolyte which transports ions but not electrons. A conventional lithium-ion battery uses a liquid electrolyte, a polymer separator, and an anode made principally of carbon (graphite) or a carbon/silicon composite. Lithium ions move from the cathode to the anode when the battery is charged and vice versa during discharge.
Conventional Lithium-Ion Battery Design
The energy density of conventional lithium-ion batteries is fundamentally limited by the anode, which provides a host material to hold the lithium ions, preventing them from binding together into pure metallic lithium. Metallic lithium, when used with conventional liquid electrolytes and porous separators, can form needle-like crystals of lithium known as dendrites, which can penetrate through the separator and short-circuit the cell.
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While using a host material is an effective way to prevent dendrites, this host material adds volume and mass to the cell, it adds cost to the battery, and it limits the battery life due to side reactions at the interface with the liquid electrolyte. The rate at which lithium diffuses through the anode also limits the maximum cell power.
The addition of silicon to a carbon anode provides a modest boost to energy density relative to a pure carbon anode. However, silicon is also a host material that not only suffers from the limitations of carbon as discussed above, but also introduces cycle life challenges as a result of the repeated expansion and contraction of the silicon particles, since silicon undergoes significantly more expansion than carbon when hosting lithium ions. Furthermore, the voltage of the lithium-silicon reaction subtracts from the overall cell voltage, reducing cell energy.
Lithium-Metal Anode Required to Unlock Highest Energy Density
We believe that a lithium-metal anode is the most promising approach that can break out of the current constraints inherent in conventional lithium-ion batteries and enable significant improvements in energy density.
In a lithium-metal battery, the anode is made of metallic lithium; there is no host material. Eliminating the host material reduces the size and weight of the battery cell and eliminates the associated materials and manufacturing costs. This results in the highest theoretical gravimetric energy density for a lithium-based battery system. Lithium-ion batteries currently used in the auto industry have energy densities of less than 300 Wh/kg. We believe lithium-metal batteries have the potential to significantly increase this energy density.
Lithium-metal anodes are compatible with conventional cathode materials, and lithium-metal batteries will derive some benefit from continued improvement in conventional cathodes. Moreover, lithium-metal anodes may enable future generations of higher energy cathodes that cannot achieve energy density gains when used with lithium-ion anodes, as shown in the figure below.
Simulated Cell Specific Energy
Simulated cell specific energy is based on traditional cell designs and architectures. Source: Andre et al, J Mater Chem A, (2015) 6709.
Although the industry has understood for 40 years the potential benefits of lithium-metal anodes, the industry has not been able to develop a separator that makes a lithium-metal anode practical for automotive use.
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Solid-State Separator Required to Enable Lithium-Metal Anode
We believe that a lithium-metal battery requires that the porous separators used in current lithium-ion batteries be replaced with a solid-state separator capable of conducting lithium ions between the cathode and anode at rates comparable to conventional liquid electrolyte while also suppressing the formation of lithium dendrites. While various solid-state separators have been shown to operate at low power densities, such low power densities are not useful for most practical applications. To our knowledge, we are the only company that has been able to demonstrate a solid-state separator for lithium-metal batteries that reliably prevents dendrite formation at higher power densities, such as those required for automotive applications and fast-charging.
We believe that our ability to develop this proprietary solid-state separator will enable the shift from lithium-ion to lithium-metal batteries.
Our Technology
* Catholyte includes an organic gel made of an organic polymer and organic liquid.
Our proprietary solid-state lithium-metal cell represents the next-generation of battery technology.
Our battery cells have none of the host materials used in conventional anodes. In fact, when our cells are manufactured there is no anode; lithium is present only in the cathode. When the cell is first charged, lithium moves out of the cathode, diffuses through our solid-state separator and plates in a thin metallic layer directly on the anode current collector, forming an anode. When the battery cell is discharged, the lithium diffuses back into the cathode.
Eliminating the anode host material found in conventional lithium-ion cells substantially increases the volumetric energy density. A pure lithium-metal anode also enables the theoretically highest gravimetric energy density for a lithium battery system.
Our proprietary solid-state separator is the core technology breakthrough that enables reliable cycling of the lithium-metal anode battery. Without a working solid-state separator, the lithium would form dendrites which would grow through a traditional porous separator and short circuit the cell.
An effective solid-state separator requires a solid material that is as conductive as a liquid electrolyte, chemically stable next to lithium–one of the most reactive elements–and able to prevent the formation of dendrites. Our team worked over ten years to develop a composition that meets these requirements and to develop the techniques necessary to manufacture the separator material at scale using a continuous process. We have a number of patents covering both the composition of this material and key steps of the manufacturing process.
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Our solid-state separator is a dense, entirely inorganic ceramic. It is made into a film that is thinner than a human hair and then cut into pieces about the length and width of a playing card. Our solid-state separator is flexible because it has a low defect density and is thin. In contrast, typical household ceramics are brittle and can break due to millions of microscopic defects which reduce structural integrity.
The separator is placed between a cathode and anode current collector to form a single battery cell layer. These single layers will be stacked together into a multi-layer cell, about the size of a deck of cards, that will be the commercial form factor for EV batteries.
Our cathodes use a combination of conventional cathode active materials (NMC) with an organic gel made of an organic polymer and organic liquid catholyte. In the future, we may use other compositions of cathode active materials, including cobalt-free compositions. We have an ongoing research and development investigation into inorganic catholyte that could replace the organic gel made of an organic polymer and organic liquid catholyte currently used.
As communicated in our solid-state battery showcase event on December 8, 2020, our single-layer solid-state cells have been extensively tested for power density, cycle life, and temperature performance. This is the only solid-state cell we are aware of that has been validated to run at automotive power densities by a leading automotive OEM. In addition, we believe our battery technology may provide significant improvements in energy density compared to today’s conventional lithium-ion batteries, as shown in the figure below.
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Benefits of Our Technology
We believe our battery technology will enable significant benefits across battery capacity, life, safety, and fast charging while minimizing cost. We believe these benefits will provide significant value to automotive OEMs by enabling greater customer adoption of their EVs. By solving key pain-points such as 15-minute fast charging, we believe our battery technology will enable the delivery of an EV experience that is significantly more competitive with fossil fuel vehicles than what today’s EVs can achieve with conventional batteries.
Our battery technology is intended to meet the five key requirements we believe will enable mass market adoption of EVs:
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Energy density. Our battery design is intended to significantly increase volumetric and gravimetric energy density by eliminating the carbon/silicon anode host material found in conventional lithium-ion cells. This increased energy density will enable EV manufacturers to increase range without increasing the size and weight of the battery pack, or to reduce the size and weight of the battery pack which will reduce the cost of the battery pack and other parts of the vehicle. For example, we estimate that our solid-state battery cells will enable a car maker to increase the range of a luxury performance EV—with 350 liters of available battery space—from 250 miles (400 km) to 450 miles (730 km) without increasing the size and weight of the battery pack. In the same example, our battery would enable the car maker to increase the maximum power output of such a vehicle from 420 kW to 650 kW without increasing the size of the battery pack. Alternatively, we believe that our solid-state battery cells will enable a car maker to increase the range of a mass market sedan—with 160 liters of available battery space—from 123 miles (200km) to 233 miles (375km) without increasing the size and weight of the battery pack. Similarly, our battery would enable the car maker to increase the maximum power output of such vehicle from 100 kW to 150 kW without increasing the size of the battery pack.
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Battery life. Our technology is expected to enable increased battery life relative to conventional lithium-ion batteries. In a conventional cell, battery life is limited by the gradual irreversible loss of lithium due to side reactions between the liquid electrolyte and the anode. By eliminating the anode host material, we expect to eliminate the side reaction and enable longer battery life. Our latest single-layer prototype cells have been tested to over 1000 cycles (under stringent test conditions, including 100% depth-of-discharge cycles at one-hour charge and discharge rates at 30 degrees Celsius with commercial-loading cathodes) while still retaining over 80% of the cells’ discharge capacity. This performance exceeds the cycle life and capacity retention in many EV battery warranties today, which may be to 150k miles to 70% of the cells’ discharge capacity.
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Fast charging capability. Our battery technology, and specifically our solid-state separator material, has been tested to demonstrate the ability to charge to approximately 80% in 15 minutes, significantly faster than commonly used high-energy EV batteries on the market. In these conventional EV batteries, the limiting factor for charge rate is the rate of diffusion of lithium ions into the anode. If a conventional battery is charged beyond these limits, lithium can start plating on carbon particles of the anode rather than diffuse into the carbon particles. This causes a reaction between the plated lithium and liquid electrolyte
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which reduces cell capacity and increases the risk of dendrites that can short circuit the cell. With a lithium-metal anode, using our solid-state separator, we expect the lithium can be plated as fast as the cathode can deliver it.
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Increased safety. Our solid-state battery cell uses a ceramic separator which is not combustible and is therefore safer than conventional polymer separators. This ceramic separator is also capable of withstanding temperatures considerably higher than those that would melt conventional polymer separators, providing an additional measure of safety. In high temperature tests of our solid-state separator material with lithium, the separator material remained stable in direct contact with molten lithium without releasing heat externally, even when heated up to 250 degrees, higher than the 180-degree melting point of lithium.
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Cost. Our battery technology eliminates the anode host material and the associated manufacturing costs, providing a structural cost advantage compared to traditional lithium-ion batteries. When comparing manufacturing facilities of similar scale, we estimate that eliminating these costs will provide a savings of approximately 17% compared to the costs of building traditional lithium-ion batteries at leading manufacturers.
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Our Competitive Strengths
Only proven lithium-metal battery technology for automotive applications to our knowledge. We have built and tested over one hundred thousand single-layer solid-state cells and have demonstrated that our technology meets automotive requirements for power, cycle life, and temperature range. In 2018, Volkswagen announced it had successfully tested certain of our single-layer, laboratory battery cells at automotive rates of power.
Partnership with one of the world’s largest automotive OEMs. We are partnered with Volkswagen, one of the largest automakers in the world. Volkswagen has been a collaboration partner and major investor since 2012 and has invested or committed to invest, subject, in certain cases, to certain closing conditions that have not yet been satisfied, a total of more than $300 million. In addition, Volkswagen has committed additional capital to fund our joint venture. Volkswagen plans to launch more than 70 new electric models and build more than 25 million vehicles on electric platforms by the end of the decade. Together with Volkswagen, we have established a joint venture to enable an industrial level of production of our solid-state batteries for use in Volkswagen vehicles. As 50-50 partners in the joint venture with Volkswagen, we expect to share equally in the revenue and profit from the joint venture.
High barriers to entry with extensive patent and intellectual property portfolio. Over the course of 10 years, we have generated more than 200 U.S. and foreign patents and patent applications – including broad fundamental patents around our core technology. Our proprietary solid-state separator uses the only material we know of that can cycle lithium at automotive current densities without forming dendrites. Our battery technology is protected by a range of patents, including patents that cover:
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Composition of matter, including the optimal composition as well as wide-ranging coverage of a number of variations;
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Enabling battery technology covering compositions and methods required to incorporate a solid-state separator into a battery;
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Manufacturing technology, protecting the way to make the separator at scale using roll-to-roll processes, without semiconductor style production or batch processes used in traditional ceramics; and
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Material dimensions, including our proprietary solid-state separator, covering any separator with commercially practical thicknesses for a solid-state battery.
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Significant development focused on next-gen technology for automotive applications. We have spent over ten years and over $300 million developing our battery technology. We have run over 2.6 million tests on over 700,000 cells and cell components. Our technical team comprises more than 250 employees, many of whom have worked at large battery manufacturers and automotive OEMs. Through its experience, our team has significant technical know-how and is supported by extensive facilities and equipment, development infrastructure, and data analytics.
Designed for volume production. Our technology is designed to use earth-abundant materials and processes suitable for high volume production. Our processes use tools which are already used at scale in the battery or ceramics industries. While preparing for scale production, we have purchased or tested production-intent tools from the world’s leading vendors. In particular, we expect to produce our proprietary separator using scalable continuous processing. Although our separator material is proprietary, the inputs are readily available and can be sourced from multiple suppliers across geographies.
Structural cost advantage leveraging industry cost trends. Aside from the separator, our battery is being designed to use many of the materials and processes that are standard across today’s battery manufacturers. As a result, we expect to benefit from the projected industry-wide cost declines for these materials that result from process improvements and economies of scale. We believe that the manufacturing of our solid-state battery cells provides us with a structural cost advantage because our battery cells are manufactured without an anode.
Our Growth Strategy
Continue to develop our commercial battery technology. We will continue developing our battery technology with the goal of enabling commercial production in 2024. We have validated capabilities of our solid-state separator and battery technology in single-layer solid-state cells at the commercially required size (70x85mm) and four-layer solid-state battery cells at a smaller size (30x30mm). We must
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now develop multi-layer cells with commercial dimensions and many more layers, to continue improving yield and performance and to optimize all components of the cell for high volume manufacturing. We will continue to work to further develop and validate the volume manufacturing processes to enable high volume manufacturing and minimize manufacturing costs. We will continue to work on increasing the yield of our separators to reduce scrappage and to increase utilization of manufacturing tools. Our current funds will enable us to expand and accelerate research and development activities and undertake additional initiatives. Finally, we will continue to use our engineering line in San Jose, California to prepare for high volume manufacturing and plan our first commercial production Pilot Facility through our joint venture partnership with Volkswagen. In addition, we expect that our recently announced QS-0 facility will help provide the additional capacity we need for our development work and will enable us to accelerate work on the next-generation of manufacturing tools. QS-0 is also intended to provide capacity to make enough batteries for hundreds of long-range battery electric test vehicles per year. This will allow us to provide early cells to Volkswagen, as well as other automotive partners, explore non-automotive applications, and help de-risk subsequent commercial scale-up. We expect to secure a long-term lease for QS-0 in the second half of this year and for QS-0 to be producing cells by 2023.
Meet Volkswagen battery demand. The Pilot Facility to be built and run by QSV Operations LLC (“QSV”) and the subsequent 20GWh expansion of the Pilot Facility (the “20GWh Expansion Facility”) would represent a small fraction of Volkswagen’s demand for batteries and implies vehicle volumes under 2% of Volkswagen’s total production in 2019, assuming a 100KWh pack size. Our goal is to significantly expand the production capacity of the joint venture, in partnership with Volkswagen, to meet more of their projected demand.
Expand partnerships with other automotive OEMs. While we expect Volkswagen will be the first to commercialize vehicles using our battery technology, over the next few years as we build our Pilot Facility, we intend to work closely with other automotive OEMs to make our solid-state battery cells widely available over time. As part of our joint venture agreement we have agreed that the Pilot Facility will be the first commercial-scale facility to manufacture our battery technology for automotive applications, but, subject to the other terms of the joint venture arrangements, we are not limited from working in parallel with other automotive OEMs to commercialize our technology. We expect that QS-0 will allow us to provide early cells to Volkswagen, as well as other automotive partners, explore non-automotive applications, and help de-risk subsequent commercial scale-up.
Expand target markets. We are currently focused on automotive EV applications, which have the most stringent set of requirements for batteries. However, we recognize that our solid-state battery technology has applicability in other large and growing markets including stationary storage and consumer electronics such as smartphones and wearables.
Expand commercialization models. Our technology is being designed to enable a variety of business models. In addition to joint ventures, such as the one with Volkswagen, we may operate solely-owned manufacturing facilities or license technology to other manufacturers, such as our recently announced QS-0 facility that is planned for the San Jose area. Where appropriate, we may build and sell separators rather than complete battery cells.
Continued investment in next-gen battery innovation. We intend to continue to invest in research and development to improve battery cell performance, improve manufacturing processes, and reduce cost.
Manufacturing and Supply
Our battery manufacturing process is being designed to be very similar to that of conventional lithium-ion battery manufacturing, with a few exceptions:
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We use a proprietary separator material instead of the polypropylene separator used in lithium-ion cells.
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Our architecture eliminates the need for anode manufacturing, reducing capital investment and lowering operating costs.
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We will build our multi-layer cells by sequentially stacking separators, cathodes and current collectors rather than winding these materials together.
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Our cell design allows us to greatly shorten the weeks-long aging process required for conventional lithium-ion cells, thus decreasing manufacturing cycle time and reducing working capital needs.
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Our architecture depends on our proprietary separator, which we will manufacture ourselves. Though our separator design is unique, its manufacturing relies on well-established, high-volume production processes currently deployed globally in other industries.
We plan to source our input materials from industry leading suppliers to the lithium-ion battery industry, and we already have strategic relationships in place with the industry’s leading vendors of cathode material, the most critical purchased input to our cell, along with leading vendors of other less critical inputs. Our separator is made from abundant materials produced at industrial scale in multiple geographies. We do not anticipate any unique supply constraints that would impede the commercialization of our product for the foreseeable future.
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Partnerships
Volkswagen Collaboration
QuantumScape has had a strong collaborative relationship with Volkswagen since 2012. Our collaboration initially focused on the testing and evaluation of QuantumScape’s battery technology. Volkswagen engineers worked closely with our engineering team and oversaw the progress on our technology development efforts and battery testing. Volkswagen has made several rounds of equity investments in QuantumScape, and senior executives of Volkswagen joined our board of directors (the “Board”), including two successive heads of group research for the Volkswagen Group. During the early part of this collaboration we worked closely with members of Volkswagen’s global research and development team, and now the QuantumScape team works closely with the Volkswagen Battery Center of Excellence, which is tasked with commercializing battery technologies within Volkswagen. The Head of Volkswagen’s Battery Center of Excellence, Frank Blome, and the Head of Volkswagen Group M&A, Investment Advisory, and Partnerships, Jens Wiese, are members of the Board.
Joint Venture Relationship
In June 2018, we formed a 50-50 joint venture entity with Volkswagen, named QSV, to facilitate the commercialization of our solid-state battery technology and enable Volkswagen to be the first automotive OEM to utilize this technology. In 2018, the parties collectively made an initial equity investment in the joint venture of approximately $3 million. Upon the occurrence of certain development milestones and subject to the entry by QuantumScape, Volkswagen and QSV into certain related agreements, QuantumScape and Volkswagen have agreed to commit additional capital on a 50-50 basis to QSV to fund the buildout of the Pilot Facility and the 20GWh Expansion Facility. As 50-50 partners in the joint venture with Volkswagen, we expect to share equally in the revenue and profit from the joint venture, including from the Pilot Facility and the 20GWh Expansion Facility.
The joint venture agreements were amended in 2020 in connection with a further $200 million investment commitment by Volkswagen in QuantumScape (subject to certain closing conditions). $100 million of this equity investment by Volkswagen was paid on December 1, 2020 and the second $100 million equity investment is subject to completion of a certain technical milestone by the end of the first quarter of 2021. As part of the first tranche of this equity investment, Volkswagen has the right to increase its representation on the Board from one member to two members. As of January 13, 2021, Volkswagen had two members on the Board.
The joint venture agreements provide for the commercialization of our solid-state battery cells to occur in two phases. The first phase is the construction of the Pilot Facility with an annual capacity of 1GWh. QSV will begin construction of the Pilot Facility when certain delivery and validation milestones are met for our solid-state battery cells. The second phase is the 20GWh Expansion Facility.
We believe the joint venture structure will enable Volkswagen to benefit from early access to our solid-state battery cells, but also protect our intellectual property. For example, certain key battery technology will continue to be owned by us and will be provided to the joint
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venture through a limited license for purposes of the Pilot Facility. The parties will agree on the license terms for a high-volume manufacturing facility for this battery technology license. The joint venture terminates upon the earliest to occur of (i) Volkswagen exercising specified put rights in the event of, amongst others, (a) a change of control of QuantumScape, or (b) the failure by us to meet specified development milestones within certain timeframes, (ii) QuantumScape or Volkswagen exercising specified call or put rights in the event of, amongst others, if the parties cannot agree to commercial terms for the Pilot Facility or 20GWh Expansion Facility within certain timeframes, (iii) a certain date after commencement of production of a Volkswagen series production vehicle using our battery cells (or an alternative end date if no such production was commenced after certain technical milestones with respect to our battery cell technology were reached) and (iv) December 31, 2028.
Volkswagen committed to purchase a certain portion of the output capacity of the Pilot Facility at a price for the solid-state battery cells that is comparable to those of lithium-ion batteries, but with a premium for the outperformance of these battery cells based on certain key technical parameters. We will sell separators to the joint venture at a price to be agreed by the parties based on the provisions of the joint venture agreements. The joint venture agreements provide the framework for the commercial relationship. At the appropriate time, the parties will negotiate agreements covering the details of these purchase commitments.
The 20GWh Expansion Facility is subject to meeting additional technical milestones and agreement on commercial terms, including pricing for the battery cells, agreement on the terms of purchase or license for the separators, and agreement on terms of the license to our battery technology for the 20GWh Expansion Facility. As 50-50 partners in the joint venture with Volkswagen, we expect to share equally in the capital contributions required for the 20GWh Expansion Facility and in the revenue and profit from the 20GWh Expansion Facility. We have agreed that the pricing for the battery cells sold by the 20GWh Expansion Facility and the separators purchased by the 20GWh Expansion Facility may be different from the pricing set for the Pilot Facility, and we will need to agree on pricing at the appropriate time. In addition, we will need to agree to the terms of the license to our battery technology.
Volkswagen is expected to have a significant role in the manufacturing ramp-up of QSV, and we have agreed that certain technology that is developed by QSV will be owned by the joint venture and licensed to each of QuantumScape and Volkswagen on a royalty-free basis. None of this intellectual property has been developed to date. Although the parties have not commenced operations on the Pilot Facility, Volkswagen has offered to assist us with supply chain, manufacturing ramp-up planning, and automation. In addition, the parties have collaborated on enabling us to develop stronger relationships with battery component supply companies, such as cathode manufacturers and equipment supply companies.
Research and Development
We conduct research and development at our headquarters facility in San Jose, California. Research and development activities concentrate on making further improvements to our battery technology, including improvements to battery performance and cost.
Our research and development currently includes programs for the following areas:
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Multi-layering. To date, we have only produced single-layer solid-state cells at the commercially required size (70x85mm) and four-layer solid-state cells at a smaller size (30x30mm). In order to produce commercially-viable solid-state battery cells for automotive applications, we must produce multi-layer battery cells which may range from several dozen to over one hundred layers, depending on our customers’ requirements, and to do so in the commercially required size. We will need substantial development and to overcome the challenges in creating these cells and implement the appropriate cell design for our solid-state battery cell.
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Improved yields. We are focused on improving the yields (useful output) of both our solid-state separators and our battery cells. We are automating our manufacturing process and purchasing larger-scale manufacturing equipment. We will need to significantly increase our yield before we can manufacture our solid-state battery cells in volume.
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Continued improvement in the solid-state separator. We are working to improve the reliability and performance of our solid-state separator, including decreasing the thickness. We have selected a method of continuous processing found at scale in both the battery and ceramic industries and are working on continuous improvement of this process. In addition, we are investigating alternative processing methods that may further increase the capital efficiency of the process.
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Continued improvement of the cathode. Our cathodes use a combination of conventional cathode active materials (NMC) along with an organic gel made of an organic polymer and organic liquid catholyte. In the future, we may use other cathode active materials, including cobalt-free compositions. We have an ongoing research and development investigation into inorganic catholyte that could replace the organic gel made of an organic polymer and organic liquid currently used.
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Integration of advanced cathode materials. We plan to benefit from industry cathode chemistry improvements and/or cost reduction. Our solid-state separator platform is being designed to enable some of the most promising next-generation cathode technologies, including high voltage or high capacity cathode active materials, which when combined with a lithium-metal anode, may further increase cell energy densities.
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Intellectual Property
The success of our business and technology leadership is supported by our proprietary battery technology. We rely upon a combination of patent, trademark and trade secret laws in the United States and other jurisdictions, as well as license agreements and other contractual protections, to establish, maintain and enforce rights in our proprietary technologies. In addition, we seek to protect our intellectual property rights through nondisclosure and invention assignment agreements with our employees and consultants and through non-disclosure agreements with business partners and other third parties. We regularly file applications for patents and have a significant number of patents in the United States and other countries where we expect to do business. Our patent portfolio is deepest in the area of solid-state separators with additional areas of strength in anodes, next-generation cathode materials, and cell, module, and pack design specific to lithium-metal batteries. Our trade secrets primarily cover manufacturing methods.
As of December 31, 2020, we owned or licensed, on an exclusive basis, 80 issued U.S. patents and 40 pending or allowed U.S. patent applications, and 103 granted foreign patents and patent applications. We have 1 registered U.S. trademark and 6 pending U.S. trademark applications. Our issued patents start expiring in 2033.
Competition
The EV market, and the battery segment in particular, is evolving and highly competitive. With the introduction of new technologies and the potential entry of new competitors into the market, we expect competition to increase in the future, which could harm our business, results of operations, or financial condition.
Our prospective competitors include major manufacturers currently supplying the industry, automotive OEMs and potential new entrants to the industry. Major companies now supplying batteries for the EV industry include Panasonic Corporation, Samsung SDI, Contemporary Amperex Technology Co. Limited, and LG-Chem Ltd. They supply conventional lithium-ion batteries and in many cases are seeking to develop solid-state batteries, including potentially lithium-metal batteries. In addition, because of the importance of electrification, most automotive OEMs are researching and investing in solid-state battery efforts and, in some cases, in battery development and production. For example, Tesla, Inc. is building multiple battery gigafactories and potentially could supply batteries to other automotive OEMs, and Toyota Motors and a Japanese consortium have a multi-year initiative pursuing solid-state batteries.
A number of development-stage companies are also seeking to improve conventional lithium-ion batteries or to develop new technologies for solid-state batteries, including lithium-metal batteries. Potential new entrants are seeking to develop new technologies for cathodes, anodes, electrolytes and additives. Some of these companies have established relationships with automotive OEMs and are in varying stages of development.
We believe our ability to compete successfully with lithium-ion battery manufacturers and with other companies seeking to develop solid-state batteries will depend on a number of factors including battery price, safety, energy density, charge rate and cycle life, and on non-technical factors such as brand, established customer relationships and financial and manufacturing resources.
Many of the incumbents have, and future entrants may have, greater resources than we have and may also be able to devote greater resources to the development of their current and future technologies. They may also have greater access to larger potential customer bases and have and may continue to establish cooperative or strategic relationships amongst themselves or with third parties (including automotive OEMs) that may further enhance their resources and offerings.
Government Regulation and Compliance
There are government regulations pertaining to battery safety, transportation of batteries, use of batteries in cars, factory safety, and disposal of hazardous materials. We will ultimately have to comply with these regulations to sell our batteries into the market. The license and sale of our batteries abroad is likely to be subject to export controls in the future.
Employees
We pride ourselves on the quality of our world-class team and seek to hire only employees dedicated to our strategic mission. Many of our employees have significant experience working with large battery manufacturers and automotive OEMS. As of December 31, 2020, we employed 276 full-time employees and 10 temporary employees, based primarily in our headquarters in San Jose, California. Over 250 of our employees are engaged in research and development and related functions, and more than half of these employees hold engineering and scientific degrees, including many from the world’s top universities.
We seek team members who want to help solve a significant problem that will positively impact the world. We value diversity and recognize the importance of fostering a positive, inclusive culture. As such, we have actively taken steps towards eliminating unconscious bias in our hiring and promotion processes while enabling us to add and promote team members who demonstrate behaviors aligned with our values.
We are committed to maintaining equitable compensation programs including equity participation. We offer market-competitive salaries and strong equity compensation aimed at attracting and retaining team members capable of making exceptional contributions to our success. Our compensation decisions are guided by the external market, role criticality, and the contributions of each team member.
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To date, we have not experienced any work stoppages and we consider our relationship with our employees to be good. None of our employees are either represented by a labor union or are subject to a collective bargaining agreement.
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Item 1A. Risk Factors.
The following summary risk factors and other information included in this Report should be carefully considered. The summary risks and uncertainties described below are not the only ones we face. Additional risks and uncertainties not currently known to us or that we currently deem less significant may also affect our business operations or financial results. If any of the following risks actually occur, our stock price, business, operating results and financial condition could be materially adversely affected. For more information, see below for more detailed descriptions of each risk factor.
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We face significant challenges in our attempt to develop a solid-state battery cell and produce it at high volumes with acceptable performance, yields and costs.
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The pace of development in materials science is often not predictable. Delays or failures in accomplishing particular development objectives may delay or prevent successful commercialization of our products.
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We may not be able to establish supply relationships for necessary materials, components or equipment or may be required to pay more than anticipated for components or equipment, which could delay the introduction of our product and negatively impact our business.
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Our relationship with Volkswagen is subject to various risks which could adversely affect our business and future prospects. There are no assurances that we will be able to commercialize solid-state batteries from our joint development relationship with Volkswagen.
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If our batteries fail to perform as expected, our ability to develop, market and sell our batteries could be harmed.
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We may not succeed in attracting customers during the development stage or for high volume commercial production, and our future growth and success depend on our ability to attract customers.
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We may be unable to adequately control the costs associated with our operations and the components necessary to build our solid-state battery cells, and, if we are unable to control these costs and achieve cost advantages in our production of our solid-state battery cells at scale, our business will be adversely affected.
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We rely heavily on our intellectual property portfolio. If we are unable to protect our intellectual property rights, our business and competitive position would be harmed.
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We may need to defend ourselves against intellectual property infringement claims or other litigation, which may be time-consuming and could cause us to incur substantial costs.
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We may not be able to accurately estimate the future supply and demand for our batteries, which could result in a variety of inefficiencies in our business and hinder our ability to generate revenue. If we fail to accurately predict our manufacturing requirements, we could incur additional costs or experience delays.
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The battery market continues to evolve, is highly competitive, and we may not be successful in competing in this industry or establishing and maintaining confidence in our long-term business prospects among current and future partners and customers.
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The trading price of our Class A Common Stock has been and may in the future continue to be subject to extreme volatility.
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We have had to restate our previously issued financial statements and in connection with such process, identified a material weakness in our internal control over financial reporting.
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The following risk factors apply to our business and operations. These risk factors are not exhaustive, and investors are encouraged to perform their own investigation with respect to our business, financial condition and prospects. We may face additional risks and uncertainties that are not presently known to us, or that we currently deem immaterial, which may also impair our business. The following discussion should be read in conjunction with the financial statements and notes to the financial statements included elsewhere in this Report.
Risks Related to Our Technology Development and Scale-Up
We face significant challenges in our attempt to develop a solid-state battery cell and produce it at high volumes with acceptable performance, yields and costs. The pace of development in materials science is often not predictable. Delays or failures in accomplishing particular development objectives may delay or prevent successful commercialization of our products.
Developing lithium-metal solid-state batteries that meet the requirements for wide adoption by automotive OEMs is a difficult undertaking and, as far as we are aware, has never been done before. We are still in development stage and face significant challenges in completing development of our multi-layer battery cells and in producing battery cells in commercial volumes. Some of the development challenges that could prevent the introduction of our solid-state battery cell include difficulties with increasing the volume, yield, reliability and uniformity of our separators and cells, increasing the size and layer count of our multi-layer cells, increasing manufacturing to produce the volume of cells needed for our technology development and customer applications, installing, bringing
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up and optimizing higher volume manufacturing equipment, packaging design and engineering to ensure adequate cycle life, cost reduction, completion of the rigorous and challenging specifications required by our automotive partners, including but not limited to, calendar life, mechanical testing, and abuse testing and development of the final manufacturing processes.
Our solid-state separators are in the development stage. These separators have never been used before for battery applications (or to our knowledge, for any other applications) and there are significant yield, cost, performance and manufacturing process challenges to be solved in order for the separators to be produced and used commercially. We are likely to encounter engineering challenges as we increase the dimensions, reduce the thickness and increase the volume of our solid-state separators. If we are not able to overcome these barriers in developing and producing its solid-state separators at commercial volumes, our business could fail.
To achieve target energy density, we need to stack our single-layer solid-state cells in a multi-layer format, which is enclosed within a single battery package. Depending upon our customer’s requirements, our battery cell may require dozens of single-layer cells within each battery package. We have tested 4-layer cells that measure 30x30mm, and recently initiated testing 4-layer cells that measure 70x85mm, but we must make multi-layer cells in a commercial form factor (70x85mm) with dozens of layers and do so at a high yield without compromising performance, and while solving related packaging challenges in a way that is scalable and low-cost. There are significant engineering and mechanical challenges that we must overcome to build our multi-layer battery cells. In addition, we will need to acquire certain tools that we currently do not possess and develop the manufacturing process necessary to make these multi-layer battery cells in high volume. If we are not able to overcome these developmental hurdles in building our multi-layer cells, our business is likely to fail.
We are evaluating multiple cathode material compositions for inclusion in our solid-state battery cells and have not yet finalized the cathode composition or formulation. We also have not validated that the current cell design, with the inclusion of an organic gel made of an organic polymer and organic liquid catholyte as part of the cathode, meets all automotive requirements. We have not yet validated a manufacturing process or acquired the tools necessary to produce high volumes of our cathode material that meets all commercial requirements. If we are not able to overcome these developmental and manufacturing hurdles our business likely will fail.
Even if we complete development and achieve volume production of our solid-state battery, if the cost, performance characteristics or other specifications of the battery fall short of our targets, our sales, product pricing and margins would likely be adversely affected.
In addition, we must advance our manufacturing processes to include more automation, such as automated stackers, and to use higher volume tools and processes, such as moving to larger continuous flow equipment. We may encounter delays or unexpected challenges in the delivery, installation and operation of the new equipment. Further, we must build QS-0 to produce engineering samples or prototype cells in the high volumes needed for our development work and to supply to prospective customers for testing. Such a project could encounter significant delays and cost overruns. We must substantially improve our manufacturing processes to increase yield and throughput to achieve the cost, performance and volume levels required for commercial shipments. In addition, our multi-layer battery cells must simultaneously satisfy all of the commercial requirements of our customers.
Any delay in the development or manufacturing scale-up of our solid-state battery cells would negatively impact our business as it will delay time to revenue and negatively impact our customer relationships. Additionally, we may encounter delays in obtaining the necessary regulatory approvals or launching our solid-state battery on the market, including delays in entering into agreements for the supply of component parts and manufacturing tools and supplies. Delays in the launching of our product would materially damage our business, prospects, financial condition, operating results and brand.
We may not be able to establish supply relationships for necessary materials, components or equipment or may be required to pay more than anticipated for components or equipment, which could delay the introduction of our product and negatively impact our business.
We rely on third-party suppliers for components and equipment necessary to develop and manufacture our solid-state batteries, including key supplies, such as our cathode material and manufacturing tools for both our separator and solid-state battery cells. We are collaborating with key suppliers but have not yet entered into agreements for the supply of production quantities of these materials. To the extent that we are unable to enter into commercial agreements with these suppliers on beneficial terms, or these suppliers experience difficulties ramping up their supply of materials to meet our requirements, the introduction of our battery will be delayed. To the extent our suppliers experience any delays in providing or developing the necessary materials, we could experience delays in delivering on our timelines.
We expect to incur significant costs related to procuring materials required to manufacture and assemble our batteries. We expect to use various materials in our batteries that will require us to negotiate purchase agreements and delivery lead-times on advantageous terms. We may not be able to control fluctuation in the prices for these materials or negotiate agreement with suppliers on terms that are beneficial to us. Our business depends on the continued supply of certain proprietary materials for our products. We are exposed to multiple risks relating to the availability and pricing of such materials and components. Substantial increases in the prices for our raw materials or components would increase our operating costs and negatively impact our prospects.
Any disruption in the supply of components, equipment or materials could temporarily disrupt research and development activities or production of our batteries until an alternative supplier is able to supply the required material. Changes in business conditions, unforeseen circumstances, governmental changes, and other factors beyond our control or which we do not presently anticipate, could also affect
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our suppliers’ ability to deliver components or equipment to us on a timely basis. Any of the foregoing could materially and adversely affect our results of operations, financial condition and prospects.
Currency fluctuations, trade barriers, tariffs or shortages and other general economic or political conditions may limit our ability to obtain key components or equipment for our solid-state batteries or significantly increase freight charges, raw material costs and other expenses associated with our business, which could further materially and adversely affect our results of operations, financial condition and prospects.
We may be unable to adequately control the costs associated with our operations and the components necessary to build our solid-state battery cells, and, if we are unable to control these costs and achieve cost advantages in our production of our solid-state battery cells at scale, our business will be adversely affected.
We require significant capital to develop and grow our business and expects to incur significant expenses, including those relating to research and development, raw material procurement, leases, sales and distribution as we build our brand and market our batteries, and general and administrative costs as we scale our operations. Our ability to become profitable in the future will not only depend on our ability to successfully market our solid-state batteries and services, but also to control our costs and achieve the target cost projections that we have, including our projected 17% cost advantage when compared to the costs of building traditional lithium-ion batteries at scale. If we are unable to cost efficiently design, manufacture, market, sell and distribute our solid-state batteries and services, our margins, profitability and prospects would be materially and adversely affected. We have not yet produced any solid-state battery cells at the commercial size or in volume and our forecasted cost advantage for the production of these cells at scale, compared to conventional lithium-ion cells, will require us to achieve rates of throughput, use of electricity and consumables, yield, and rate of automation demonstrated for mature battery, battery material, and ceramic manufacturing processes, that we have not yet achieved. If we are unable to achieve these targeted rates, our business will be adversely impacted. In particular, while we have estimated that eliminating the anode host material and the associated manufacturing costs will provide a savings in production at scale of approximately 17% compared to the costs of building traditional lithium-ion batteries at leading manufacturers, that estimate is subject to numerous assumptions and uncertainties. To achieve those savings we will need to achieve significant cost savings in battery design and manufacturing, in addition to the cost savings associated with the elimination of an anode from our solid-state battery cells, while controlling costs associated with the manufacture of our solid-state separator, including achieving substantial improvements in throughput and yield required to hit commercial targets. Further, we will need to capture industry cost savings in the materials, components, equipment, and processes that we share, notably in the cathode, cell design, and factory. We cannot be certain that we will achieve these cost savings or that future efficiency improvements in lithium-ion battery manufacturing will not reduce or eliminate these estimated cost savings.
We rely on complex machinery for our operations, and production involves a significant degree of risk and uncertainty in terms of operational performance and costs.
We rely heavily on complex machinery for our operations and the production of our solid-state battery cells, and this equipment has not yet been qualified to operate at large-scale manufacturing. The work required to integrate this equipment into the production of our solid-state battery cells is time intensive and requires us to work closely with the equipment provider to ensure that it works properly for our unique battery technology. This integration work will involve a significant degree of uncertainty and risk and may result in the delay in the scaling up of production or result in additional cost to our battery cells.
Both our pilot manufacturing facilities and our large-scale manufacturing facility will require large-scale machinery. Such machinery is likely to suffer unexpected malfunctions from time to time and will require repairs and spare parts to resume operations, which may not be available when needed. Unexpected malfunctions of our production equipment may significantly affect the intended operational efficiency. In addition, because this equipment has not been used to build solid-state battery cells, the operational performance and costs associated with this equipment can be difficult to predict and may be influenced by factors outside of our control, such as, but not limited to, failures by suppliers to deliver necessary components of our products in a timely manner and at prices and volumes acceptable to us, environmental hazards and remediation, difficulty or delays in obtaining governmental permits, damages or defects in systems, industrial accidents, fires, seismic activity and other natural disasters.
Operational problems with our manufacturing equipment could result in the personal injury to or death of workers, the loss of production equipment, damage to manufacturing facilities, monetary losses, delays and unanticipated fluctuations in production. In addition, operational problems may result in environmental damage, administrative fines, increased insurance costs and potential legal liabilities. All of these operational problems could have a material adverse effect on our business, results of operations, cash flows, financial condition or prospects.
Customer Risks and Risks Related to Our Partnership with Volkswagen
Our relationship with Volkswagen is subject to various risks which could adversely affect our business and future prospects. There are no assurances that we will be able to commercialize solid-state batteries from our joint development relationship with Volkswagen.
We and Volkswagen have formed a joint venture to collaborate on the manufacturing ramp up of our solid-state battery cell.
There is no assurance that we will be able to complete the development of the solid-state battery cells in the time frame required by the joint venture arrangements. If we do not complete this development in a timely manner, Volkswagen may terminate its participation in
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the joint venture. Our joint venture arrangements with Volkswagen provide a framework for our cooperation and requires that we and Volkswagen enter into certain additional arrangements regarding the purchase by the joint venture of solid-state separators from us, the purchase and pricing of the solid-state battery cells that will be produced by the joint venture and sold to Volkswagen, and the terms for licensing our technology to the joint venture. There can be no assurance that we will be able to agree with Volkswagen on these key elements on terms that are financially beneficial for us or that we will be able to enter into the additional arrangements, including any purchase orders, with Volkswagen for commercialization under the joint venture arrangements.
The commercial terms of the purchase by Volkswagen of the output of the joint venture will depend on the performance of our solid-state battery and the demand for the vehicles that Volkswagen develops to utilize the solid-state battery cells that will be produced by the joint venture. If we cannot complete the development of our solid-state battery cells, Volkswagen does not select our solid-state battery cell for commercialization or if there is a delay in the introduction of the Volkswagen vehicles that intend to use our solid-state battery cells, our business will be harmed.
The strong relationship that we have developed with Volkswagen and rights under the joint venture agreement may deter other automotive OEMs from working closely with us. If we are not able to expand our other customer relationships, or if we become too dependent on Volkswagen for our revenue, our business could be harmed.
Volkswagen may have economic, business or legal interests or goals that are inconsistent with our goals. Any significant disagreements with Volkswagen may impede our ability to maximize the benefits of our partnerships and slow the commercialization of our solid-state battery. Our joint venture arrangements may require us, among other things, to pay certain costs or to make certain capital investments or to seek Volkswagen’s consent to take certain actions. In addition, if Volkswagen is unable or unwilling to meet its economic or other obligations under the joint venture arrangements, we may be required to either fulfill those obligations alone to ensure the ongoing success of the joint venture or to dissolve and liquidate the joint venture. These factors could result in a material adverse effect on our business and financial results.
If our batteries fail to perform as expected, our ability to develop, market, and sell our batteries could be harmed.
Once commercial production of our solid-state battery cells commences, our batteries may contain defects in design and manufacture that may cause them to not perform as expected or that may require repairs, recalls, and design changes. Our batteries are inherently complex and incorporate technology and components that have not been used for other applications and that may contain defects and errors, particularly when first introduced. We have a limited frame of reference from which to evaluate the long-term performance of our solid-state batteries. There can be no assurance that we will be able to detect and fix any defects in our solid-state batteries prior to the sale to potential consumers. If our batteries fail to perform as expected, we could lose design wins and customers may delay deliveries, terminate further orders or initiate product recalls, each of which could adversely affect our sales and brand and could adversely affect our business, prospects, and results of operations.
We may not succeed in attracting customers during the development stage or for high volume commercial production, and our future growth and success depend on our ability to attract customers.
We may not succeed in attracting customers during the development stage or for high volume commercial production. For example, we may be unsuccessful at attracting additional customers for QS-0, in which case we may have excess capacity. In addition, if we are unable to attract new customers in need of high-volume commercial production of our products, our business may suffer.
Many of our potential customers tend to be large enterprises. Therefore, our future success will depend on our ability to effectively sell our products to such large customers. Sales to these end-customers involve risks that may not be present (or that are present to a lesser extent) with sales to smaller customers. These risks include, but are not limited to, (i) increased purchasing power and leverage held by large customers in negotiating contractual arrangements with us and (ii) longer sales cycles and the associated risk that substantial time and resources may be spent on a potential end-customer that elects not to purchase our solutions.
Our potential customers that are large organizations often undertake a significant evaluation process that results in a lengthy sales cycle. In addition, product purchases by large organizations are frequently subject to budget constraints, multiple approvals and unanticipated administrative, processing and other delays. Finally, large organizations typically have longer implementation cycles, require greater product functionality and scalability, require a broader range of services, demand that vendors take on a larger share of risks, require acceptance provisions that can lead to a delay in revenue recognition and expect greater payment flexibility. All of these factors can add further risk to business conducted with these potential customers.
If the Put or Call Rights under our joint venture agreements with Volkswagen are exercised, it may have an adverse effect on our liquidity or our stockholders’ ownership could be diluted.
The joint venture structure we agreed to with Volkswagen is intended, in part, to protect our intellectual property. Certain key battery technology will continue to be owned by us and will be provided to the joint venture through a limited license for purposes of QS-1. We and Volkswagen still need to agree on the license terms for this battery technology license for the QS-1 Expansion. The joint venture terminates upon the earliest to occur of (i) Volkswagen exercising specified put rights in the event of, amongst others, (a) a change of control of our company, or (b) the failure by us to meet specified development milestones within certain timeframes, (ii) us exercising specified call rights or Volkswagen exercising specified put rights if, among other things, the parties cannot agree to commercial terms
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for QS-1 or QS-1 Expansion within certain timeframes, (iii) a certain date after commencement of production of a Volkswagen series production vehicle using our battery cells (or an alternative end date if no such production was commenced after certain technical milestones with respect to our battery cell technology were reached) and (iv) December 31, 2028.
We may not have sufficient funds, borrowing capacity, or other capital resources available to pay for the interests of Volkswagen in cash if it exercises its put rights or to exercise our call rights. Such lack of available funds upon the exercising by Volkswagen of its put rights or by us of our call rights could force us to issue stock at a time we might not otherwise desire to do so in order to purchase the interests of Volkswagen. If we are required or choose to purchase those interests from Volkswagen, we could experience significant cash outflow, our other stockholders could see their holdings diluted through the issuance of shares to finance such payment obligations, and our financial condition and the price of our Class A Common Stock may be adversely affected.
We may not be able to accurately estimate the future supply and demand for our batteries, which could result in a variety of inefficiencies in our business and hinder our ability to generate revenue. If we fail to accurately predict our manufacturing requirements, we could incur additional costs or experience delays.
It is difficult to predict our future revenues and appropriately budget for our expenses, and we may have limited insight into trends that may emerge and affect our business. We anticipate being required to provide forecasts of our demand to our current and future suppliers prior to the scheduled delivery of products to potential customers. Currently, there is no historical basis for making judgments on the demand for our batteries or our ability to develop, manufacture, and deliver batteries, or our profitability in the future. If we overestimate our requirements, our suppliers may have excess inventory, which indirectly would increase our costs. If we underestimate our requirements, our suppliers may have inadequate inventory, which could interrupt manufacturing of our products and result in delays in shipments and revenues. In addition, lead times for materials and components that our suppliers order may vary significantly and depend on factors such as the specific supplier, contract terms and demand for each component at a given time. If we fail to order sufficient quantities of product components in a timely manner, the delivery of batteries to our potential customers could be delayed, which would harm our business, financial condition and operating results.
Our future growth and success are dependent upon consumers’ willingness to adopt EVs.
Our growth and future demand for our products is highly dependent upon the adoption by consumers of alternative fuel vehicles in general and EVs in particular. The market for new energy vehicles is still rapidly evolving, characterized by rapidly changing technologies, competitive pricing and competitive factors, evolving government regulation and industry standards, and changing consumer demands and behaviors. If the market for EVs in general does not develop as expected, or develops more slowly than expected, our business, prospects, financial condition and operating results could be harmed.
Concentration of ownership among Volkswagen and our executive officers, directors and their affiliates may prevent new investors from influencing significant corporate decisions.
As of April 29, 2021, Volkswagen beneficially owns approximately 26% of our Class A Common Stock and 12% of our Class B Common Stock outstanding, representing 14% of the vote, and our executive officers, directors and their affiliates as a group beneficially own approximately 35% of our Class A Common Stock and 63% of our Class B Common Stock outstanding, representing 60% of the vote. As a result, these stockholders will be able to exercise a significant level of control over all matters requiring stockholder approval, including the election of directors, any amendment of our amended and restated certificate of incorporation (the “Certificate of Incorporation”) and approval of significant corporate transactions. In addition, Volkswagen holds the right to designate two directors to our Board. This control could have the effect of delaying or preventing a change of control or changes in our management and will make the approval of certain transactions difficult or impossible without the support of these stockholders and of their votes.
Our Intellectual Property Risks
We rely heavily on our intellectual property portfolio. If we are unable to protect our intellectual property rights, our business and competitive position would be harmed.
We may not be able to prevent unauthorized use of our intellectual property, which could harm our business and competitive position. We rely upon a combination of the intellectual property protections afforded by patent, copyright, trademark and trade secret laws in the United States and other jurisdictions, as well as license agreements and other contractual protections, to establish, maintain and enforce rights in our proprietary technologies. In addition, we seek to protect our intellectual property rights through nondisclosure and invention assignment agreements with our employees and consultants, and through non-disclosure agreements with business partners and other third parties. Despite our efforts to protect our proprietary rights, third parties, including our business partners, may attempt to copy or otherwise obtain and use our intellectual property without our consent. Monitoring unauthorized use of our intellectual property is difficult and costly, and the steps we have taken or will take to prevent misappropriation may not be sufficient. Any enforcement efforts we undertake, including litigation, could be time-consuming and expensive and could divert management’s attention, which could harm our business, results of operations and financial condition. In addition, existing intellectual property laws and contractual remedies may afford less protection than needed to safeguard our intellectual property portfolio.
Patent, copyright, trademark and trade secret laws vary significantly throughout the world. A number of foreign countries do not protect intellectual property rights to the same extent as do the laws of the United States. Therefore, our intellectual property rights may not be
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as strong or as easily enforced outside of the United States and efforts to protect against the unauthorized use of our intellectual property rights, technology and other proprietary rights may be more expensive and difficult outside of the United States. Failure to adequately protect our intellectual property rights could result in our competitors using our intellectual property to offer products, potentially resulting in the loss of some of our competitive advantage and a decrease in our revenue which, would adversely affect our business, prospects, financial condition and operating results.
We may need to defend ourselves against intellectual property infringement claims, which may be time-consuming and could cause us to incur substantial costs.
Companies, organizations or individuals, including our current and future competitors, may hold or obtain patents, trademarks or other proprietary rights that would prevent, limit or interfere with our ability to make, use, develop or sell our products, which could make it more difficult for us to operate our business. From time to time, we may receive inquiries from third parties inquiring whether we are infringing their intellectual property rights and/or seek court declarations that they do not infringe upon our intellectual property rights. Companies holding patents or other intellectual property rights relating to batteries, electric motors or electronic power management systems may bring suits alleging infringement of such rights or otherwise asserting their rights and seeking licenses. In addition, if we are determined to have infringed upon a third party’s intellectual property rights, we may be required to do one or more of the following:
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cease selling, incorporating or using products that incorporate the challenged intellectual property;
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pay substantial damages;
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obtain a license from the holder of the infringed intellectual property right, which license may not be available on reasonable terms or at all; or
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redesign our batteries.
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In the event of a successful claim of infringement against us and our failure or inability to obtain a license to the infringed technology on reasonable terms, our business, prospects, operating results and financial condition could be materially adversely affected. In addition, any litigation or claims, whether or not well-founded, could result in substantial costs and diversion of resources and management’s attention.
We also license patents and other intellectual property from third parties, and we may face claims that our use of this intellectual property infringes the rights of others. In such cases, we may seek indemnification from our licensors under our license contracts with them. However, our rights to indemnification may be unavailable or insufficient to cover our costs and losses, depending on our use of the technology, whether we choose to retain control over conduct of the litigation, and other factors.
Our patent applications may not result in issued patents or our patent rights may be contested, circumvented, invalidated or limited in scope, any of which could have a material adverse effect on our ability to prevent others from interfering with our commercialization of our products.
Our patent applications may not result in issued patents, which may have a material adverse effect on our ability to prevent others from commercially exploiting products similar to ours. The status of patents involves complex legal and factual questions and the breadth of claims allowed is uncertain. As a result, we cannot be certain that the patent applications that we file will result in patents being issued, or that our patents and any patents that may be issued to us will afford protection against competitors with similar technology. Numerous patents and pending patent applications owned by others exist in the fields in which we have developed and are developing our technology. Any of our existing or pending patents may be challenged by others on the basis that they are invalid or unenforceable. Furthermore, patent applications filed in foreign countries are subject to laws, rules and procedures that differ from those of the United States, and thus we cannot be certain that foreign patent applications related to issued U.S. patents will be issued.
Even if our patent applications succeed and we are issued patents in accordance with them, we are still uncertain whether these patents will be contested, circumvented, invalidated or limited in scope in the future. The rights granted under any issued patents may not provide us with meaningful protection or competitive advantages, and some foreign countries provide significantly less effective patent enforcement than in the United States. In addition, the claims under any patents that issue from our patent applications may not be broad enough to prevent others from developing technologies that are similar or that achieve results similar to ours. The intellectual property rights of others could also bar us from licensing and exploiting any patents that issue from our pending applications. In addition, patents issued to us may be infringed upon or designed around by others and others may obtain patents that we need to license or design around, either of which would increase costs and may adversely affect our business, prospects, financial condition and operating results.
Our Business Risks
The battery market continues to evolve, is highly competitive, and we may not be successful in competing in this industry or establishing and maintaining confidence in our long-term business prospects among current and future partners and customers.
The battery market in which we compete continues to evolve and is highly competitive. To date, we have focused our efforts on our lithium-metal solid-state battery technology, which is being designed to outperform conventional lithium-ion battery technology. However, lithium-ion battery technology has been widely adopted and our current competitors have, and future competitors may have, greater resources than we do and may also be able to devote greater resources to the development of their current and future technologies.
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These competitors also may have greater access to customers and may be able to establish cooperative or strategic relationships amongst themselves or with third parties that may further enhance their resources and competitive positioning. In addition, lithium-ion battery manufacturers may continue to reduce cost and expand supply of conventional batteries and therefore reduce the prospects for our business or negatively impact the ability for us to sell our products at a market-competitive price and yet at sufficient margins.
Many automotive OEMs are researching and investing in solid-state battery efforts and, in some cases, in battery development and production. There are a number of companies seeking to develop alternative approaches to solid-state battery technology, including lithium-metal batteries. We expect competition in battery technology and EVs to intensify due to increased demand for these vehicles and a regulatory push for EVs, continuing globalization, and consolidation in the worldwide automotive industry. Developments in alternative technologies or improvements in batteries technology made by competitors may materially adversely affect the sales, pricing and gross margins of our batteries. If a competing technology is developed that has superior operational or price performance, our business will be harmed. Similarly, if we fail to accurately predict and ensure that our battery technology can address customers’ changing needs or emerging technological trends, or if our customers fail to achieve the benefits expected from our solid-state batteries, our business will be harmed.
We must continue to commit significant resources to develop our battery technology in order to establish a competitive position, and these commitments will be made without knowing whether such investments will result in products potential customers will accept. There is no assurance we will successfully identify new customer requirements, develop and bring our batteries to market on a timely basis, or that products and technologies developed by others will not render our batteries obsolete or noncompetitive, any of which would adversely affect our business and operating results.
Customers will be less likely to purchase our batteries if they are not convinced that our business will succeed in the long term. Similarly, suppliers and other third parties will be less likely to invest time and resources in developing business relationships with us if they are not convinced that our business will succeed in the long term. Accordingly, in order to build and maintain our business, we must maintain confidence among current and future partners, customers, suppliers, analysts, ratings agencies and other parties in our long-term financial viability and business prospects. Maintaining such confidence may be particularly complicated by certain factors including those that are largely outside of our control, such as our limited operating history, market unfamiliarity with our products, any delays in scaling manufacturing, delivery and service operations to meet demand, competition and uncertainty regarding the future of EVs and our eventual production and sales performance compared with market expectations.
If we are unable to attract and retain key employees and qualified personnel, our ability to compete could be harmed.
Our success depends on our ability to attract and retain our executive officers, key employees and other qualified personnel, and our operations may be severely disrupted if we lost their services. As we build our brand and become more well known, there is increased risk that competitors or other companies will seek to hire our personnel. None of our employees are bound by a non-competition agreement. The failure to attract, integrate, train, motivate and retain these personnel could seriously harm our business and prospects.
In addition, we are highly dependent on the services of Jagdeep Singh, our Chief Executive Officer, and other senior technical and management personnel, including our executive officers, who would be difficult to replace. If Mr. Singh or other key personnel were to depart, we may not be able to successfully attract and retain senior leadership necessary to grow our business.
We are an early stage company with a history of financial losses and expect to incur significant expenses and continuing losses for the foreseeable future.
We incurred a net loss of approximately $1,681.8 million for the year ended December 31, 2020 and an accumulated deficit of approximately $1,977.6 million from our inception in 2010 through the year ended December 31, 2020. We believe that we will continue to incur operating and net losses each quarter until at least the time we begin significant production of our lithium-metal solid-state batteries, which is not expected to occur until 2024, and may occur later.
We expect the rate at which we will incur losses to be significantly higher in future periods as we, among other things, continue to incur significant expenses in connection with the design, development and manufacturing of our batteries; expand our research and development activities; invest in manufacturing capabilities; build up inventories of components for our batteries; increase our sales and marketing activities; develop our distribution infrastructure; and increase our general and administrative functions to support our growing operations. We may find that these efforts are more expensive than we currently anticipate or that these efforts may not result in revenues, which would further increase our losses.
We have been, and may in the future be, adversely affected by the global COVID-19 pandemic.
We face various risks related to epidemics, pandemics, and other outbreaks, including the recent COVID-19 pandemic. The impact of COVID-19, including changes in consumer and business behavior, pandemic fears and market downturns, and restrictions on business and individual activities, has created significant volatility in the global economy and led to reduced economic activity. The spread of COVID-19 has also impacted our potential customers and our suppliers by disrupting the manufacturing, delivery and overall supply chain of battery, EV and equipment manufacturers and suppliers and has led to a global decrease in battery and EV sales in markets around the world.
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The pandemic has resulted in government authorities implementing numerous measures to try to contain the virus, such as travel bans and restrictions, quarantines, stay-at-home or shelter-in-place orders, and business shutdowns. For example, employees at our headquarters located in San Jose, California are subject to a stay-at-home order from the state and local governments. These measures limit operations in our San Jose headquarters and have and may continue to adversely impact our employees, research and development activities and operations and the operations of our suppliers, vendors and business partners, and may negatively impact our sales and marketing activities. In addition, various aspects of our business cannot be conducted remotely, including many aspects of the development and manufacturing of our solid-state material and our battery cells. These measures by government authorities may remain in place for a significant period of time and they are likely to continue to adversely affect our future manufacturing plans, sales and marketing activities, business and results of operations. We may take further actions as may be required by government authorities or that we determine are in the best interests of our employees, suppliers, vendors and business partners.
The extent to which the COVID-19 pandemic continues to impact our business, prospects and results of operations will depend on future developments, which are highly uncertain and cannot be predicted, including the duration and spread of the pandemic, its severity, the actions to contain the virus or treat its impact, and how quickly and to what extent normal economic and operating activities can resume. Even after the COVID-19 pandemic has subsided, we may continue to experience an adverse impact to our business as a result of the global economic impact, including any recession that has occurred or may occur in the future.
There are no comparable recent events that may provide guidance as to the effect of the spread of COVID-19, and, as a result, the ultimate impact of the COVID-19 pandemic or a similar health epidemic is highly uncertain.
Our expectations and targets regarding the times when we will achieve various technical, pre-production and production objectives depend in large part upon assumptions and analyses developed by us. If these assumptions or analyses prove to be incorrect, we may not achieve these milestones when expected or at all.
Our expectations and targets regarding the times when we will achieve various technical, pre-production and production objectives reflect our current expectations and estimates. Whether we will achieve these objectives when we expect depends on a number of factors, many of which are outside our control, including, but not limited to:
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success and timing of development activity;
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unanticipated technical or manufacturing challenges or delays;
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technological developments relating to lithium-ion, lithium-metal solid-state or other batteries that could adversely affect the commercial potential of our technologies;
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whether we can obtain sufficient capital to build our manufacturing facilities and sustain and grow our business;
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adverse developments in our joint venture relationship with Volkswagen, including termination of the joint venture or delays in negotiating commercial terms for QS-1 or QS-1 Expansion;
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our ability to manage our growth;
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whether we can manage relationships with key suppliers;
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our ability to retain existing key management, integrate recent hires and attract, retain and motivate qualified personnel; and
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the overall strength and stability of domestic and international economies.
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Unfavorable changes in any of these or other factors, most of which are beyond our control, could materially and adversely affect our ability to achieve our objectives when planned and our business, results of operations and financial results.
From time to time, we may be involved in litigation, regulatory actions or government investigations and inquiries, which could have an adverse impact on our profitability and consolidated financial position.
We may be involved in a variety of litigation, other claims, suits, regulatory actions or government investigations and inquiries and commercial or contractual disputes that, from time to time, are significant.
For example, on December 11, 2020, a putative class action lawsuit was filed in the New York State Supreme Court by a purported QuantumScape warrantholder against the Company. We removed the case to federal court. On March 25, 2021, plaintiff amended the complaint to drop the class allegations. The amended complaint alleges, among other things, that plaintiff was entitled to exercise his warrants within 30 days of the closing of the business combination between QuantumScape and Kensington (the “Closing”) and that the proxy statement/prospectus/information statement dated September 21, 2020 and November 12, 2020 is misleading and/or omits material information concerning the exercise of the warrants. The complaint seeks monetary damages for alleged breach of contract, securities law violations, fraud, and negligent misrepresentation.
On December 24, 2020, a lawsuit was filed in the New York State Supreme Court by three purported QuantumScape warrantholders against the Company. The complaint alleges, among other things, that the plaintiffs were entitled to exercise warrants within 30 days of Closing. The complaint also alleges that the proxy statement/prospectus/information statement dated September 21, 2020 and November 12, 2020 is misleading and/or omits material information concerning the exercise of the warrants. The complaint generally seeks monetary damages for alleged breach of contract.
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Between January 5, 2021 and January 8, 2021, three putative class action lawsuits were filed in the Northern District of California by purported purchasers of QuantumScape securities against the Company and its Chief Executive Officer or against the Company and certain members of management and the Board of Directors, and VGA.
All three complaints allege that the defendants purportedly made false and/or misleading statements and failed to disclose material adverse facts about our business, operations, and prospects, including information regarding our battery technology. One complaint alleges a purported class that includes all persons who purchased or acquired our securities between December 8, 2020 and December 31, 2020. The other two complaints allege a purported class that includes all persons who purchased or acquired our securities between November 27, 2020 and December 31, 2020. On April 20, 2021, the three actions were consolidated, with the Court appointing lead plaintiff and counsel.
Two shareholder derivative suits were also filed in February 2021 against 11 officers and directors of the Company and have been consolidated into one action. QuantumScape is the nominal defendant. The complaints in the derivative action allege that the individual defendants breached various duties to the Company and contains additional similar allegations based on the same general allegations in the class action complaints described immediately above. VGA was also named as a defendant in the derivative litigation.
On February 26, 2021, a former consultant submitted a demand for arbitration to JAMS, claiming that the Company breached an obligation to extend the term of his consulting agreement. The arbitration demand seeks either 804,350 shares of QuantumScape or damages equal to the value of such shares.
In addition, from time to time, we may also be involved in legal proceedings and investigations arising in the normal course of business including, without limitation, commercial or contractual disputes, including warranty claims and other disputes with potential customers and suppliers; intellectual property matters; personal injury claims; environmental issues; tax matters; and employment matters.
It is difficult to predict the outcome or ultimate financial exposure, if any, represented by these matters, and there can be no assurance that any such exposure will not be material. Such claims may also negatively affect our reputation.
We may become subject to product liability claims, which could harm our financial condition and liquidity if we are not able to successfully defend or insure against such claims.
We may become subject to product liability claims, even those without merit, which could harm our business, prospects, operating results, and financial condition. We face inherent risk of exposure to claims in the event our batteries do not perform as expected or malfunction resulting in personal injury or death. Our risks in this area are particularly pronounced given our batteries have not yet been commercially tested or mass produced. A successful product liability claim against us could require us to pay a substantial monetary award. Moreover, a product liability claim could generate substantial negative publicity about our batteries and business and inhibit or prevent commercialization of other future battery candidates, which would have a material adverse effect on our brand, business, prospects and operating results. Any insurance coverage might not be sufficient to cover all potential product liability claims. Any lawsuit seeking significant monetary damages either in excess of our coverage, or outside of our coverage, may have a material adverse effect on our reputation, business and financial condition. We may not be able to secure additional product liability insurance coverage on commercially acceptable terms or at reasonable costs when needed, particularly if we do face liability for our products and are forced to make a claim under our policy.
Our batteries and our website, systems, and data we maintain may be subject to intentional disruption, other security incidents, or alleged violations of laws, regulations, or other obligations relating to data handling that could result in liability and adversely impact our reputation and future sales.
We expect to face significant challenges with respect to information security and maintaining the security and integrity of our systems and other systems used in our business, as well as with respect to the data stored on or processed by these systems. Advances in technology, an increased level of sophistication, and expertise of hackers, and new discoveries in the field of cryptography can result in a compromise or breach of the systems used in our business or of security measures used in our business to protect confidential information, personal information, and other data.
The availability and effectiveness of our batteries, and our ability to conduct our business and operations, depend on the continued operation of information technology and communications systems, some of which we have yet to develop or otherwise obtain the ability to use. Systems used in our business, including data centers and other information technology systems, will be vulnerable to damage or interruption. Such systems could also be subject to break-ins, sabotage and intentional acts of vandalism, as well as disruptions and security incidents as a result of non-technical issues, including intentional or inadvertent acts or omissions by employees, service providers, or others. We anticipate using outsourced service providers to help provide certain services, and any such outsourced service providers face similar security and system disruption risks as us. Some of the systems used in our business will not be fully redundant, and our disaster recovery planning cannot account for all eventualities. Any data security incidents or other disruptions to any data centers or other systems used in our business could result in lengthy interruptions in our service and may adversely affect our business, prospects, financial condition and operating results.
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Our facilities or operations could be damaged or adversely affected as a result of natural disasters and other catastrophic events.
Our facilities or operations could be adversely affected by events outside of our control, such as natural disasters, wars, health epidemics such as the ongoing COVID-19 pandemic, and other calamities. We cannot assure you that any backup systems will be adequate to protect us from the effects of fire, floods, typhoons, earthquakes, power loss, telecommunications failures, break-ins, war, riots, terrorist attacks or similar events. Any of the foregoing events may give rise to interruptions, breakdowns, system failures, technology platform failures or internet failures, which could cause the loss or corruption of data or malfunctions of software or hardware as well as adversely affect our ability to provide services.
Any financial or economic crisis, or perceived threat of such a crisis, including a significant decrease in consumer confidence, may materially and adversely affect our business, financial condition, and results of operations.
In recent years, the United States and global economies suffered dramatic downturns as the result of the COVID-19 pandemic, a deterioration in the credit markets and related financial crisis as well as a variety of other factors including, among other things, extreme volatility in security prices, severely diminished liquidity and credit availability, ratings downgrades of certain investments and declining valuations of others. The United States and certain foreign governments have taken unprecedented actions in an attempt to address and rectify these extreme market and economic conditions by providing liquidity and stability to the financial markets. If the actions taken by these governments are not successful, the return of adverse economic conditions may negatively impact the demand for our solid-state battery cells and may negatively impact our ability to raise capital, if needed, on a timely basis and on acceptable terms or at all.
Our ability to utilize our net operating loss and tax credit carryforwards to offset future taxable income may be subject to certain limitations.
In general, under Section 382 of the Code, a corporation that undergoes an “ownership change” is subject to limitations on its ability to use its pre-change net operating loss carryforwards (“NOLs”), to offset future taxable income. The limitations apply if a corporation undergoes an “ownership change,” which is generally defined as a greater than 50 percentage point change (by value) in its equity ownership by certain stockholders over a three-year period. If we have experienced an ownership change at any time since our incorporation, we may already be subject to limitations on our ability to utilize our existing NOLs and other tax attributes to offset taxable income or tax liability. In addition future changes in our stock ownership, which may be outside of our control, may trigger an ownership change. Similar provisions of state tax law may also apply to limit our use of accumulated state tax attributes. As a result, even if we earn net taxable income in the future, our ability to use it or our pre-change NOL carryforwards and other tax attributes to offset such taxable income or tax liability may be subject to limitations, which could potentially result in increased future income tax liability to us.
There is also a risk that changes in law or regulatory changes made in response to the need for some jurisdictions to raise additional revenue to help counter the fiscal impact from the COVID-19 pandemic or for other unforeseen reasons, including suspensions on the use of net operating losses or tax credits, possibly with retroactive effect, may result in our existing net operating losses or tax credits expiring or otherwise being unavailable to offset future income tax liabilities. A temporary suspension of the use of certain net operating losses and tax credits has been enacted in California, and other states may enact suspensions as well.
We are subject to anti-corruption, anti-bribery, anti-money laundering, financial and economic sanctions and similar laws, and non-compliance with such laws can subject us to administrative, civil and criminal fines and penalties, collateral consequences, remedial measures and legal expenses, all of which could adversely affect our business, results of operations, financial condition and reputation.
We are subject to anti-corruption, anti-bribery, anti-money laundering, financial and economic sanctions and similar laws and regulations in various jurisdictions in which we conduct or in the future may conduct activities, including the U.S. Foreign Corrupt Practices Act (“FCPA”), the U.K. Bribery Act 2010, and other anti-corruption laws and regulations. The FCPA and the U.K. Bribery Act 2010 prohibit us and our officers, directors, employees and business partners acting on our behalf, including agents, from corruptly offering, promising, authorizing or providing anything of value to a “foreign official” for the purposes of influencing official decisions or obtaining or retaining business or otherwise obtaining favorable treatment. The FCPA also requires companies to make and keep books, records and accounts that accurately reflect transactions and dispositions of assets and to maintain a system of adequate internal accounting controls. The U.K. Bribery Act also prohibits non-governmental “commercial” bribery and soliciting or accepting bribes. A violation of these laws or regulations could adversely affect our business, results of operations, financial condition and reputation. Our policies and procedures designed to ensure compliance with these regulations may not be sufficient and our directors, officers, employees, representatives, consultants, agents, and business partners could engage in improper conduct for which we may be held responsible.
Non-compliance with anti-corruption, anti-bribery, anti-money laundering or financial and economic sanctions laws could subject us to whistleblower complaints, adverse media coverage, investigations, and severe administrative, civil and criminal sanctions, collateral consequences, remedial measures and legal expenses, all of which could materially and adversely affect our business, results of operations, financial condition and reputation. In addition, changes in economic sanctions laws in the future could adversely impact our business and investments in our Class A Common Stock.
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Our insurance coverage may not be adequate to protect us from all business risks.
We may be subject, in the ordinary course of business, to losses resulting from products liability, accidents, acts of God, and other claims against us, for which we may have no insurance coverage. As a general matter, the policies that we do have may include significant deductibles or self-insured retentions, and we cannot be certain that our insurance coverage will be sufficient to cover all future losses or claims against us. A loss that is uninsured or which exceeds policy limits may require us to pay substantial amounts, which could adversely affect our financial condition and operating results.
Our management has limited experience in operating a public company.
Some of our executive officers have limited experience in the management of a publicly traded company. Our management team may not successfully or effectively manage our transition to a public company that will be subject to significant regulatory oversight and reporting obligations under federal securities laws. Certain executives’ limited experience in dealing with the increasingly complex laws pertaining to public companies could be a significant disadvantage in that it is likely that an increasing amount of their time may be devoted to these activities which will result in less time being devoted to the management and growth of our Company. We may not have adequate personnel with the appropriate level of knowledge, experience, and training in the accounting policies, practices or internal controls over financial reporting required of public companies in the United States.
We will incur significant increased expenses and administrative burdens as a public company, which could have an adverse effect on our business, financial condition and results of operations.
We will face increased legal, accounting, administrative and other costs and expenses as a public company that we did not incur as a private company. The Sarbanes-Oxley Act of 2002 (the “Sarbanes-Oxley Act”), including the requirements of Section 404, as well as rules and regulations subsequently implemented by the SEC, the Dodd-Frank Wall Street Reform and Consumer Protection Act of 2010 and the rules and regulations promulgated and to be promulgated thereunder, the PCAOB and the securities exchanges, impose additional reporting and other obligations on public companies. The development and implementation of the standards and controls necessary for us to achieve the level of accounting standards required of a public company in the United States may require costs greater than expected. It is possible that we will be required to expand our employee base and hire additional employees to support our operations as a public company which will increase our operating costs in future periods.
Compliance with public company requirements will increase costs and make certain activities more time-consuming. A number of those requirements will require us to carry out activities we have not done previously. For example, we have created new Board committees and adopted new internal controls and disclosure controls and procedures. In addition, expenses associated with SEC reporting requirements will be incurred. Furthermore, if any issues in complying with those requirements are identified, such as our restatement of our previously issued consolidated financial statements and related material weakness as described in this Report and as further described in the “Risks Related to Restatement of our Consolidated Financial Statements”, we have incurred and could incur additional costs rectifying those or new issues, and the existence of these issues could adversely affect our reputation or investor perceptions of it. It will also be more expensive to obtain director and officer liability insurance. Risks associated with our status as a public company may make it more difficult to attract and retain qualified persons to serve on our Board or as executive officers. The additional reporting and other obligations imposed by these rules and regulations will increase legal and financial compliance costs and the costs of related legal, accounting and administrative activities. These increased costs will require us to divert a significant amount of money that could otherwise be used to expand the business and achieve strategic objectives. Advocacy efforts by stockholders and third parties may also prompt additional changes in governance and reporting requirements, which could further increase costs.
If securities or industry analysts do not publish or cease publishing research or reports about us, our business, or the market in which we operate, or if they change their recommendations regarding our securities adversely, the price and trading volume of our securities could decline.
The trading market for our securities will be influenced by the research and reports that industry or securities analysts may publish about us, our business, market or competitors. Securities and industry analysts do not currently, and may never, publish research on us. If no securities or industry analysts commence coverage of us, our share price and trading volume would likely be negatively impacted. If any of the analysts who may cover us change their recommendation regarding our shares of Class A Common Stock adversely, or provide more favorable relative recommendations about our competitors, the price of our shares of Class A Common Stock would likely decline. If any analyst who may cover us were to cease our coverage of us or fail to regularly publish reports on it, we could lose visibility in the financial markets, which in turn could cause our share price or trading volume to decline.
Our Regulatory Risks
We are subject to substantial regulation and unfavorable changes to, or failure by us to comply with, these regulations could substantially harm our business and operating results.
Our batteries, and the sale of EVs and motor vehicles in general, are subject to substantial regulation under international, federal, state and local laws, including export control laws. We expect to incur significant costs in complying with these regulations. Regulations related to the battery and EV industry and alternative energy are currently evolving and we face risks associated with changes to these regulations.
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To the extent the laws change, our products may not comply with applicable international, federal, state or local laws, which would have an adverse effect on our business. Compliance with changing regulations could be burdensome, time consuming, and expensive. To the extent compliance with new regulations is cost prohibitive, our business, prospects, financial condition and operating results would be adversely affected.
Internationally, there may be laws in jurisdictions we have not yet entered or laws we are unaware of in jurisdictions we have entered that may restrict our sales or other business practices. The laws in this area can be complex, difficult to interpret and may change over time. Continued regulatory limitations and other obstacles that may interfere with our ability to commercialize our products could have a negative and material impact on our business, prospects, financial condition and results of operations.
We are subject to requirements relating to environmental and safety regulations and environmental remediation matters which could adversely affect our business, results of operation and reputation.
We are subject to numerous federal, state and local environmental laws and regulations governing, among other things, solid and hazardous waste storage, treatment and disposal, and remediation of releases of hazardous materials. There are significant capital, operating and other costs associated with compliance with these environmental laws and regulations. Environmental laws and regulations may become more stringent in the future, which could increase costs of compliance or require us to manufacture with alternative technologies and materials.
Federal, state and local authorities also regulate a variety of matters, including, but not limited to, health, safety and permitting in addition to the environmental matters discussed above. New legislation and regulations may require us to make material changes to our operations, resulting in significant increases to the cost of production.
Our manufacturing process will have hazards such as but not limited to hazardous materials, machines with moving parts, and high voltage and/or high current electrical systems typical of large manufacturing equipment and related safety incidents. There may be safety incidents that damage machinery or product, slow or stop production, or harm employees. Consequences may include litigation, regulation, fines, increased insurance premiums, mandates to temporarily halt production, workers’ compensation claims, or other actions that impact our company brand, finances, or ability to operate.
Our failure to timely and effectively implement controls and procedures required by Section 404(a) of the Sarbanes-Oxley Act could have a material adverse effect on our business.
We will be required to provide management’s attestation on internal controls. The standards required for a public company under Section 404(a) of the Sarbanes-Oxley Act are significantly more stringent than those that were required of us as a privately-held company. Management may not be able to effectively and timely implement controls and procedures that adequately respond to the increased regulatory compliance and reporting requirements. If we are not able to implement the additional requirements of Section 404(a) in a timely manner or with adequate compliance, we may not be able to assess whether our internal controls over financial reporting are effective, which may subject us to adverse regulatory consequences and could harm investor confidence and the market price of our securities.
We qualify as an “emerging growth company” within the meaning of the Securities Act, and if we take advantage of certain exemptions from disclosure requirements available to emerging growth companies, this could make our securities less attractive to investors and may make it more difficult to compare our performance with other public companies.
We qualify as an “emerging growth company” as defined in Section 2(a)(19) of the Securities Act, as modified by the JOBS Act. As such, we are eligible for and intend to take advantage of certain exemptions from various reporting requirements applicable to other public companies that are not emerging growth companies for as long as we continue to be an emerging growth company, including (i) the exemption from the auditor attestation requirements with respect to internal control over financial reporting under Section 404(b) of the Sarbanes-Oxley Act, (ii) the exemptions from say-on-pay, say-on-frequency and say-on-golden parachute voting requirements and (iii) reduced disclosure obligations regarding executive compensation in our periodic reports and proxy statements. As a result, the stockholders may not have access to certain information they may deem important. We will remain an emerging growth company until the earliest of (i) the last day of the fiscal year in which the market value of the common stock that is held by non-affiliates exceeds $700 million as of June 30 of that fiscal year, (ii) the last day of the fiscal year in which we have total annual gross revenue of $1.07 billion or more during such fiscal year (as indexed for inflation), (iii) the date on which we have issued more than $1 billion in non-convertible debt in the prior three-year period or (iv) the last day of the fiscal year following the fifth anniversary of the date of the first sale of units in Kensington’s initial public offering. In addition, Section 107 of the JOBS Act also provides that an emerging growth company can take advantage of the exemption from complying with new or revised accounting standards provided in Section 7(a)(2)(B) of the Securities Act as long as we are an emerging growth company. An emerging growth company can therefore delay the adoption of certain accounting standards until those standards would otherwise apply to private companies. We have elected not to opt out of such extended transition period and, therefore, we may not be subject to the same new or revised accounting standards as other public companies that are not emerging growth companies. Investors may find our Class A Common Stock less attractive because we will rely on these exemptions, which may result in a less active trading market for our Class A Common Stock and its price may be more volatile.
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Risks Related to Ownership of Our Common Stock and Our Certificate of Incorporation and Bylaws Provisions
Our Class A Common Stock has been and may in the future continue to be subject to extreme volatility.
The trading price of our Class A Common Stock has been and may in the future continue to be subject to extreme volatility. For example, from November 27, 2020, the date our Class A Common Stock began trading on the NYSE, through March 31, 2021, our Class A Common Stock has experienced an intra-day trading high of $132.73 per share and an intra-day trading low of $24.50 per share. At certain times during such period, the daily fluctuations in the trading price of our Class A Common Stock were substantially greater than 10%. We cannot predict the magnitude of future fluctuations in the trading price of our Class A Common Stock. The trading price of our Class A Common Stock may be affected by a number of factors, including events described in the risk factors set forth in this Annual Report and in our other reports filed with the SEC from time to time, as well as our operating results, financial condition and other events or factors. Any of the factors listed below could have a material adverse effect on your investment in our securities. Factors affecting the trading price of our securities may include:
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announcements by us or our competitors regarding technical developments and levels of performance achieved by our or their battery technologies;
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announcements by us regarding the timing of our production objectives, including regarding QS-0 and QS-1;
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announcements by us or Volkswagen regarding developments in our relationship with Volkswagen;
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our ability to bring our products and technologies to market on a timely basis, or at all;
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our operating results or development efforts failing to meet the expectation of securities analysts or investors in a particular period;
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actual or anticipated fluctuations in our quarterly financial results or the quarterly financial results of companies perceived to be similar to it;
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changes in the market’s expectations about our operating results or the EV industry;
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success of competitors actual or perceived development efforts;
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changes in financial estimates and recommendations by securities analysts concerning the Company or the battery industry in general;
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operating and share price performance of other companies that investors deem comparable to the Company;
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disputes or other developments related to proprietary rights, including patents, litigation matters and our ability to obtain intellectual property protection for our technologies;
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changes in laws and regulations affecting our business;
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our ability to meet compliance requirements;
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commencement of, or involvement in, litigation involving the Company;
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changes in our capital structure, such as future issuances of securities or the incurrence of additional debt;
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the volume of shares of Class A Common Stock available for public sale;
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the level of demand for our stock, including the amount of short interest in our Class A Common Stock;
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any major change in our Board or management;
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sales of substantial amounts of the shares of Class A Common Stock by our directors, executive officers or significant stockholders or the perception that such sales could occur;
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the expiration of contractual lock-up agreements with our executive officers, directors and stockholders, which we have entered into, a significant portion of which expire in May 2021, and any future agreements we may enter into in the future from time to time; and
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general economic and political conditions such as recessions, interest rates, fuel prices, international currency fluctuations and acts of war or terrorism.
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Broad market and industry factors may materially harm the market price of our securities irrespective of our operating performance. The stock market in general, and the NYSE in particular, have experienced price and volume fluctuations that have often been unrelated or disproportionate to the operating performance of the particular companies affected. The trading prices and valuations of these stocks, and of our securities, may not be predictable. A loss of investor confidence in the market for retail stocks or the stocks of other companies which investors perceive to be similar to the Company could depress our share price regardless of our business, prospects, financial
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conditions or results of operations. A decline in the market price of our securities also could adversely affect our ability to issue additional securities and our ability to obtain additional financing in the future.
Following certain periods of volatility in the market price of our securities, we may become subject of securities litigation. We have experienced, and may in the future experience additional litigation following periods of volatility. This type of litigation may result in substantial costs and a diversion of management’s attention and resources.
Additionally, the volatility of the stock directly impacts the fair value of the Assumed Common Stock Warrants; hence, continued volatility in our stock price could result in a corresponding volatility in the fair value of the liability associated with the Assumed Common Stock Warrants.
Short sellers may engage in manipulative activity that could drive down the market price of our Class A Common Stock.
Short selling is the practice of selling securities that the seller does not own but rather has borrowed or intends to borrow from a third party with the intention of later buying lower priced identical securities to return to the lender. Accordingly, it is in the interest of a short seller of our Class A Common Stock for the price to decline. Some short sellers publish, or arrange for the publication of, opinions or characterizations regarding which may create negative market momentum. Issuers, like us, whose securities have historically had limited trading volumes and/or have been susceptible to relatively high volatility levels can be particularly vulnerable to such short seller attacks. No assurances can be made that similar declines in the market price of our Class A Common Stock will not occur in the future, in connection with the activities of short sellers.
Sales of substantial amounts of our Class A Common Stock in the public markets, or the perception that such sales could occur, could reduce the price that our Class A Common Stock might otherwise attain.
Sales of a substantial number of shares of our Class A Common Stock in the public market after our March 2021 Public Offering or in connection with the expiration of certain lock-up contractual agreements in May 2021, or the perception that such sales could occur, could adversely affect the market price of our Class A Common Stock and may make it more difficult for you to sell your Class A Common Stock at a time and price that you deem appropriate. As of April 29, 2021, we have approximately 259,611,491 shares of Class A Common Stock and 146,362,452 shares of Class B Common Stock outstanding. All of the shares of Class A Common Stock sold in the March 2021 Public Offering are freely tradable without restrictions or further registration under the Securities Act, except for any shares sold to any of our “affiliates” as defined in Rule 144 under the Securities Act.
In connection with the Business Combination Agreement and the transactions contemplated by the Business Combination Agreement, certain holders of the Company’s securities entered into a Registration Rights and Lock-Up Agreement, and certain other lock-up agreements, pursuant to which they agreed to certain restrictions on the transfer of QuantumScape securities.
In addition, in connection with the March 2021 Public Offering, (i) we agreed that, without the prior written consent of Goldman Sachs & Co. LLC and Morgan Stanley & Co. LLC on behalf of the underwriters and subject to certain exceptions, we will not offer, sell, or agree to sell, directly or indirectly, any Company securities for a period of 90 days from the date of the final prospectus relating to the March 2021 Public Offering, and (ii) each of our directors and executive officers agreed with the underwriters, subject to certain exceptions, not to dispose of or hedge any shares of our common stock or securities convertible into or exchangeable for shares of our common stock during the period from the date of such agreement continuing through May 21, 2021, except with the prior written consent of Goldman Sachs & Co. LLC and Morgan Stanley & Co. LLC.
Certain stockholders are entitled to require us to register shares owned by them for public sale in the United States, and we have filed a Registration Statement on Form S-1 (Registration No. 333-251433) (the “Resale S-1”), which the SEC has previously declared effective, to register those shares. However, such Resale S-1 must be amended in connection with the restatement and the SEC will need to declare the amended Resale S-1 effective. In addition, we have filed a registration statement to register shares reserved for future issuance under our equity compensation plans. Subject to there being effective registration statements covering the sales of such shares, the satisfaction of applicable exercise periods and expiration of the lock-up agreements referred to above, the shares issued upon exercise of outstanding stock options and settlement of outstanding restricted stock units will be available for immediate resale in the United States in the open market.
Purchasers of our Class A Common Stock in our March 2021 Public Offering incurred immediate and substantial dilution.
Investors who purchased Class A Common Stock in our March 2021 Public Offering paid a price per share that substantially exceeds the book value of our tangible assets after subtracting our liabilities. This dilution is due to the substantially lower price paid by our investors who purchased shares prior to our March 2021 Public Offering as compared to the price offered to the public in our March 2021 Public Offering, and any previous exercise of stock options granted to our service providers. In addition, as of March 31, 2021, options to purchase shares of our Class A Common Stock and warrants to purchase shares of our Class A Common Stock were outstanding, as set forth elsewhere in this Report and the exercise of any of these options or warrants would result in additional dilution. As a result of this dilution, investors who purchased shares in our March 2021 Public Offering may receive less than the purchase price they paid in our March 2021 Public Offering, if anything, in the event of our liquidation.
We have broad discretion in the use of the net proceeds from our March 2021 Public Offering and may not use them effectively.
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Our management has broad discretion in the application of the net proceeds from our March 2021 Public Offering, including to provide sufficient funding to build the larger version of QS-0, to fund QS-0 operating expenses, to fund our share of the equity portion of the joint venture’s costs of building the QS-1 Expansion, net of debt intended to be incurred by the joint venture, and for working capital and general corporate purposes, and we may spend or invest these proceeds in a way with which our stockholders disagree. Because of the number and variability of factors that will determine our use of the net proceeds from our March 2021 Public Offering, our ultimate use of such proceeds may vary substantially from our currently intended use.
The failure by our management to apply these proceeds effectively could harm our business, and we may invest such proceeds in a manner that does not produce income or that loses value, which may negatively impact the market price of our common stock.
Our business model of manufacturing solid-state batteries is capital-intensive, and we may not be able to raise additional capital on attractive terms, if at all, which could be dilutive to stockholders. If we cannot raise additional capital when needed, our operations and prospects could be materially and adversely affected.
The development, design, manufacture and sale of batteries is a capital-intensive business, which we currently finance through joint venture arrangements and other third-party financings. As a result of the capital-intensive nature of our business, we can be expected to continue to sustain substantial operating expenses without generating sufficient revenues to cover expenditures. Over time, we expect that we will need to raise additional funds, including through entry into new or extending existing joint venture arrangements, through the issuance of equity, equity-related or debt securities or through obtaining credit from financial institutions to fund, together with our principal sources of liquidity, ongoing costs such as research and development relating to our batteries, the construction of large factories, any significant unplanned or accelerated expenses, and new strategic investments. We cannot be certain that additional capital will be available on attractive terms, if at all, when needed, which could be dilutive to stockholders, and our financial condition, results of operations, business and prospects could be materially and adversely affected.
The dual class structure of our Common Stock has the effect of concentrating voting control with the current holders of Class B Common Stock. This will limit or preclude the ability of other stockholders to influence corporate matters, including the outcome of important transactions, including a change in control.
Shares of Class B Common Stock have 10 votes per share, while shares of Class A Common Stock have one vote per share. Although no one holder or group of holders has control of more than 30% of the voting power of our capital stock, as of April 29, 2021 the holders of the Class B Common Stock control approximately 84% of the voting power of our capital stock and therefore collectively control matters submitted to our stockholders for approval, including the election of directors, amendments of our organizational documents and any merger, consolidation, sale of all or substantially all of our assets or other major corporate transactions. Even though these holders are not party to any agreement that requires them to vote together, they may have interests that differ from yours and may vote in a way with which you disagree and which may be adverse to your interests. This concentrated control may have the effect of delaying, preventing or deterring a change in control of us, could deprive our stockholders of an opportunity to receive a premium for their capital stock as part of a sale of us, and might ultimately affect the market price of shares of our Class A Common Stock.
Anti-takeover provisions in our Certificate of Incorporation, Bylaws and Delaware law could make an acquisition of us more difficult, limit attempts by our stockholders to replace or remove our management and limit the market price of our Class A Common Stock.
The Certificate of Incorporation, amended and restated Bylaws (the “Bylaws”) and Delaware law contain provisions which could have the effect of rendering more difficult, delaying or preventing an acquisition deemed undesirable by our Board. These provisions include:
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authorizing “blank check” preferred stock, which could be issued by our Board without stockholder approval and may contain voting, liquidation, dividend and other rights superior to the Common Stock;
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limiting the liability of, and providing indemnification to, our directors and officers;
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prohibiting cumulative voting in the election of directors;
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providing that vacancies on our Board may be filled only by majority of directors then in office of our Board, even though less than a quorum;
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prohibiting the ability of our stockholders to call special meetings;
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establishing an advance notice procedure for stockholder proposals to be brought before an annual meeting, including proposed nominations of persons for election to our Board;
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requiring that, once there are no longer any outstanding shares of the Class B Common Stock, any action to be taken by our stockholders be effected at a duly called annual or special meeting and not by written consent;
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specifying that special meetings of our stockholders can be called only by a majority of our Board, the chair of our Board, or our Chief Executive Officer;
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requiring that, once there are no longer any outstanding shares of Class B Common Stock, the approval of holders of at least two-thirds of the outstanding voting securities to amend the Bylaws and certain provisions of the Certificate of Incorporation; and
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reflecting two classes of Common Stock.
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These provisions may frustrate or prevent any attempts by our stockholders to replace or remove our current management by making it more difficult for stockholders to replace members of our Board, which is responsible for appointing the members of our management. In addition, because we are incorporated in Delaware, we are governed by the provisions of Section 203 of the Delaware General Corporation Law (“DGCL”), which generally prohibits a Delaware corporation from engaging in any of a broad range of business combinations with any “interested” stockholder for a period of three years following the date on which the stockholder became an “interested” stockholder.
Our Bylaws provide, subject to limited exceptions, that the Court of Chancery of the State of Delaware and the federal district courts of the United States will be the sole and exclusive forum for certain stockholder litigation matters, which could limit our stockholders’ ability to obtain a chosen judicial forum for disputes with us or our directors, officers, employees or stockholders.
Our Bylaws provide that, unless otherwise consented to by us in writing, the Court of Chancery of the State of Delaware (or, if the Court of Chancery does not have jurisdiction, another State court in Delaware or the federal district court for the District of Delaware) shall, to the fullest extent permitted by law, be the sole and exclusive forum for the following types of actions or proceedings: (i) any derivative action or proceeding brought on behalf of the Company; (ii) any action asserting a claim of breach of a fiduciary duty owed by, or otherwise wrongdoing by, any of our directors, officers, or other employees to us or our stockholders; (iii) any action arising pursuant to any provision of the DGCL or the Certificate of Incorporation or the Bylaws; (iv) any action to interpret, apply, enforce or determine the validity of the Certificate of Incorporation or the Bylaws; or (v) any other action asserting a claim that is governed by the internal affairs doctrine, in all cases subject to the court having jurisdiction over indispensable parties named as defendants. This provision would not apply to suits brought to enforce a duty or liability created by the Securities Exchange Act of 1934, as amended, or any other claim for which the U.S. federal courts have exclusive jurisdiction. The Bylaws further provide that, unless otherwise consented to by the Company in writing, the federal district courts of the United States will be the sole and exclusive forum for the resolution of any complaint asserting a cause of action arising under the Securities Act.
Any person or entity purchasing or otherwise acquiring any interest in our securities shall be deemed to have notice of and consented to this provision. This choice of forum provision may limit a stockholder’s ability to bring a claim in a judicial forum of its choosing for disputes with the Company or any of our directors, officers, other employees or stockholders, which may discourage lawsuits with respect to such claims. There is uncertainty as to whether a court would enforce such provisions, and the enforceability of similar choice of forum provisions in other companies’ charter documents has been challenged in legal proceedings. It is possible that a court could find these types of provisions to be inapplicable or unenforceable, and if a court were to find the choice of forum provision contained in the Bylaws to be inapplicable or unenforceable in an action, we may incur additional costs associated with resolving such action in other jurisdictions, which could harm our business, operating results and financial condition.
Our dual class structure may depress the trading price of the Class A Common Stock.
We cannot predict whether our dual class structure will result in a lower or more volatile market price of the Class A Common Stock or in adverse publicity or other adverse consequences. For example, certain index providers have announced restrictions on including companies with multiple-class share structures in certain of their indexes. S&P Dow Jones and FTSE Russell have announced changes to their eligibility criteria for inclusion of shares of public companies on certain indices, including the S&P 500, pursuant to which companies with multiple classes of shares of common stock are excluded. In addition, several stockholder advisory firms have announced their opposition to the use of multiple class structures. As a result, the dual class structure of our Common Stock may cause stockholder advisory firms to publish negative commentary about our corporate governance practices or otherwise seek to cause us to change our capital structure. Any such exclusion from indices or any actions or publications by stockholder advisory firms critical of our corporate governance practices or capital structure could adversely affect the value and trading market of the Class A Common Stock.
We do not expect to declare any dividends in the foreseeable future.
We do not anticipate declaring any cash dividends to holders of our Common Stock in the foreseeable future. Consequently, investors may need to rely on sales of their shares after price appreciation, which may never occur, as the only way to realize any future gains on their investment.
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There can be no assurance that we will be able to comply with the continued listing standards of the NYSE.
In connection with the Closing, we listed our Class A Common Stock and Public Warrants on the NYSE under the symbols “QS” and “QS.WS”, respectively. If the NYSE delists our securities from trading on its exchange for failure to meet the listing standards and we are not able to list such securities on another national securities exchange, we expect such securities could be quoted on an over-the-counter market. If this were to occur, we and our stockholders could face significant material adverse consequences including:
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a limited availability of market quotations for our securities;
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reduced liquidity for our securities;
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a limited amount of news and analyst coverage; and
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a decreased ability to issue additional securities or obtain additional financing in the future.
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Risks Related to Our Assumed Common Stock Warrants
We may redeem unexpired Assumed Common Stock Warrants prior to their exercise at a time that is disadvantageous to Warrantholders.
The Public Warrants are currently exercisable for one share of Class A Common Stock at a price of $11.50 per share. We have the ability to redeem outstanding warrants at any time starting July 30, 2021 for the Public Warrants and prior to their expiration, at a price of $0.01 per warrant, provided that the last reported sales price of Class A Common Stock equals or exceeds $18.00 per share for any 20 trading days within a 30-trading day period ending on the third trading day prior to the date we send the notice of redemption to warrantholders and provided certain other conditions are met. None of the Private Placement Warrants will be redeemable by us on such terms so long as they are held by the Sponsor or its permitted transferees. If and when the warrants become redeemable by us, we may exercise our redemption rights even if we are unable to register or qualify the underlying securities for sale under all applicable state securities laws. As a result, we may redeem the warrants as set forth above even if the holders are otherwise unable to exercise the warrants. Redemption of the outstanding warrants could force warrantholders (i) to exercise their warrants and pay the exercise price therefor at a time when it may be disadvantageous for them to do so, (ii) to sell their warrants at the then-current market price when they might otherwise wish to hold their warrants or (iii) to accept the nominal redemption price which, at the time the outstanding warrants are called for redemption, we expect would be substantially less than the market value of their warrants.
In addition, we have the ability to redeem outstanding Assumed Common Stock Warrants starting September 28, 2021 for $0.10 per warrant upon a minimum of 30 days’ prior written notice of redemption provided that holders will be able to exercise their warrants prior to redemption for a number of Class A Common Stock determined based on the redemption date and the fair market value of Class A Common Stock and provided certain other conditions are met. We would redeem the warrants in this manner when we believe it is in our best interest to update our capital structure to remove the warrants and pay fair market value to the warrantholders. We can also redeem the warrants for Class A Common Stock when the Class A Common Stock is trading at a price starting at $10.00, which is below the exercise price of $11.50, because it will provide certainty with respect to our capital structure and cash position while providing our warrantholders with fair market value in the form of shares of our Class A Common Stock. If we choose to redeem our warrants when the Class A Common Stock is trading at a price below the exercise price of our warrants, this could result in our warrantholders receiving fewer shares of our Class A Common Stock than they would have received if they had chosen to wait to exercise their warrants for shares of Class A Common Stock if and when the Class A Common Stock trades at a price higher than the exercise price of $11.50. Any such redemption may have similar consequences to a cash redemption described above. In addition, such redemption may occur at a time when our warrants are “out-of-the-money,” in which case they would lose any potential embedded value from a subsequent increase in the value of the Class A Common Stock had their warrants remained outstanding. Finally, this redemption feature provides a ceiling to the value of their Warrants since it locks in the redemption price in the number of Class A Common Stock to be received if we choose to redeem the warrants for Class A Common Stock.
Risks Related to Restatement of Our Consolidated Financial Statements
We have had to restate our previously issued consolidated financial statements and as part of that process have identified a material weakness in our internal control over financial reporting as of December 31, 2020. If we are unable to develop and maintain an effective system of internal control over financial reporting, we may not be able to accurately report our financial results in a timely manner, which may adversely affect investor confidence in us and materially and adversely affect our business and operating results.
On April 28, 2021, after consultation with Ernst & Young, our Audit Committee and management concluded that, in light of the Staff Statement, it was appropriate to restate our previously issued consolidated financial statements as of and for the period ended December 31, 2020. As part of the restatement process, we have identified a material weakness in our internal control over financial reporting.
A material weakness is a deficiency, or a combination of deficiencies, in internal control over financial reporting such that there is a reasonable possibility that a material misstatement of our annual or interim financial statements will not be prevented, or detected and corrected on a timely basis. Effective internal controls are necessary for us to provide reliable financial reports and prevent fraud. We continue to evaluate steps to remediate the material weaknesses. These remediation measures may be time consuming and costly and there is no assurance that these initiatives will ultimately have the intended effects.
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If we identify any new material weaknesses in the future, any such newly identified material weakness could limit our ability to prevent or detect a misstatement of our accounts or disclosures that could result in a material misstatement of our annual or interim financial statements. In such case, we may be unable to maintain compliance with securities law requirements regarding timely filing of periodic reports in addition to applicable stock exchange listing requirements, investors may lose confidence in our financial reporting and our stock price may decline as a result. We cannot assure you that the measures we have taken to date, or any measures we may take in the future, will be sufficient to avoid potential future material weaknesses.
We may face litigation and other risks as a result of the restatement and material weakness in our internal control over financial reporting.
As part of the restatement, we identified material weaknesses in our internal controls over financial reporting. As a result of such material weakness, the restatement, the change in accounting for the Assumed Common Stock Warrants, and other matters raised or that may in the future be raised by the SEC, we face potential for litigation or other disputes which may include, among others, claims invoking the federal and state securities laws, contractual claims or other claims arising from the Restatement and the material weakness in our internal control over financial reporting and the preparation of our financial statements. As of the date of this Report, we have no knowledge of any such litigation or dispute. However, we can provide no assurance that such litigation or dispute will not arise in the future. Any such litigation or dispute, whether successful or not, could have a material adverse effect on our business, results of operations and financial condition.
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