Ultium
Ultium is a modular electric vehicle battery and propulsion architecture developed by General Motors (GM), enabling scalable energy storage, flexible vehicle designs, and enhanced performance across a range of battery electric vehicles (BEVs).[1] Introduced in March 2020, the platform utilizes pouch-style battery cells with nickel-manganese-cobalt (NMC) chemistry, arranged in configurable modules to support energy capacities from 50 kWh to over 200 kWh, allowing for driving ranges up to 450 miles or more in certain applications.[1] Its design emphasizes cost efficiency, with GM targeting battery costs below $100 per kWh through economies of scale and optimized manufacturing.[2] The Ultium platform integrates not only batteries but also electric motors and power electronics, forming a unified "Ultium Drive" system that supports all-wheel drive configurations and rapid charging capabilities up to 350 kW.[3] Key innovations include a flexible skateboard chassis that positions the battery pack low for improved handling and stability, as well as bidirectional charging for vehicle-to-home (V2H) energy transfer.[4] Initially powered by large-format pouch cells measuring approximately 58 cm by 10 cm, the technology has evolved to incorporate diverse chemistries, such as lithium iron phosphate (LFP) for cost-effective, longer-life applications in entry-level models.[5] Production of Ultium batteries is handled by Ultium Cells LLC, a joint venture between GM and LG Energy Solution established in 2019, with facilities in Ohio, Tennessee, and Michigan designed to produce more than 130 GWh annually by the mid-2020s to meet North American EV demand.[6] As of 2025, Ultium Cells continues to expand, including upgrades to its Spring Hill, Tennessee plant for LFP cell production and joint development of lithium manganese-rich (LMR) cells for high-energy applications in trucks and SUVs.[7][8] The platform powers GM's growing EV lineup, including models like the Chevrolet Silverado EV, GMC Hummer EV, and Cadillac Escalade IQ, contributing to GM's goal of an all-electric portfolio by 2035.[9] In October 2024, GM announced it would discontinue the "Ultium" branding for its EV batteries and related technologies to reflect a broader strategy incorporating multiple cell types and suppliers, though the underlying architecture and Ultium Cells operations persist under the established name.[10] This shift aligns with GM's increased investments in EV infrastructure, totaling over $35 billion through 2025, positioning Ultium's legacy as a foundational element in the company's electrification efforts.[11]Development History
Origins and Announcement
In late 2019, under the leadership of CEO Mary Barra, General Motors accelerated its strategic pivot toward electric vehicles by announcing a major joint venture with LG Energy Solution to develop and produce advanced battery cells for the North American market. This partnership, structured as a 50/50 collaboration, was formally established on December 5, 2019, to support GM's growing emphasis on electrification amid intensifying competition in the automotive industry. The initiative marked a foundational step in GM's broader commitment to transitioning its portfolio to zero-emission vehicles, building on earlier efforts like the 2016 Chevrolet Bolt EV launch.[12][13] The joint venture received its official name, Ultium Cells LLC, in May 2020, aligning with the broader branding of GM's emerging EV ecosystem. This naming reflected the venture's role in scaling battery production to meet ambitious electrification targets. Meanwhile, GM's EV strategy gained public prominence on March 4, 2020, during its dedicated EV Day event, where Barra unveiled the Ultium platform—a comprehensive battery and propulsion architecture designed to underpin a diverse lineup of electric vehicles. The reveal featured early vehicle concepts, including the Cadillac Lyriq luxury SUV, signaling Ultium's application across passenger cars, trucks, and SUVs.[14][1][15][16] To fuel this transformation, GM committed $35 billion through 2025 to investments in electric and autonomous vehicle development, with Ultium at the core of its third-generation battery electric vehicle (BEV3) architecture.[11] Early objectives for the platform emphasized scalability, enabling adaptation to various vehicle sizes and types while targeting up to 400 miles of estimated range on a full charge and 0-80% charging in about 20 minutes using a 350 kW DC fast charger. This modular battery design served as a key enabler, allowing flexible configurations to optimize performance and efficiency across models.[17][1]Key Milestones and Partnerships
In 2021, General Motors launched the GMC Hummer EV, the first production vehicle utilizing the Ultium platform, with initial deliveries commencing in December. Battery cell production at the joint venture Ultium Cells facility in Warren, Ohio, began in August 2022, supporting the ramp-up of Hummer EV output and marking the start of commercial-scale Ultium manufacturing. During 2022 and 2023, Ultium expanded its production footprint with new facilities in Spring Hill, Tennessee, and Lansing, Michigan; the Tennessee plant, initially announced in 2021, saw a $275 million investment in December 2022 to increase capacity from 35 GWh to 50 GWh annually, while construction advanced toward operations starting in 2024. Concurrently, GM formed key partnerships to advance Ultium technology, including a 2020 agreement with Honda extended in 2022 for co-developing affordable electric vehicles based on the Ultium platform, though the collaboration was terminated in October 2023 due to strategic shifts. In March 2021, GM partnered with SolidEnergy Systems to integrate lithium-metal battery innovations into Ultium cells, aiming for higher energy density and lower costs by 2023. In October 2024, GM announced it would discontinue the "Ultium" branding for its EV batteries and related technologies to reflect a broader strategy incorporating multiple cell types and suppliers, though the underlying architecture and Ultium Cells operations persist.[10] In May 2025, GM and LG Energy Solution announced plans to commercialize lithium manganese-rich (LMR) prismatic battery cells through Ultium Cells, targeting higher energy density for future electric trucks and SUVs with production slated for 2028. Later that year, in July, Ultium Cells outlined upgrades to the Tennessee facility for lithium iron phosphate (LFP) cell production, enabling low-cost battery packs for entry-level models by late 2027 and integrating these chemistries into the existing modular framework. However, market challenges prompted an indefinite pause of Phase 2 expansion at the Ultium CAM cathode active material plant in Bécancour, Quebec, announced in October 2025, as the industry adjusted to slower electric vehicle adoption. These developments coincided with significant workforce adjustments in 2025, including layoffs of approximately 1,200 employees at GM's Factory Zero in Michigan and 550 at the Ohio Ultium Cells plant, linked to temporary production pauses at the Ohio and Tennessee facilities until mid-2026 to facilitate upgrades amid softening demand.Battery Technology
Chemistry and Composition
Ultium batteries primarily employ a nickel-cobalt-manganese-aluminum (NCMA) cathode chemistry paired with a graphite anode, designed to achieve high energy density at the cell level of approximately 280 Wh/kg.[18][19] This composition reduces cobalt usage by up to 70% compared to earlier nickel-manganese-cobalt (NMC) formulations while enhancing overall capacity and stability for electric vehicle applications.[20] The cells adopt a pouch format, which provides structural flexibility and enables efficient stacking to accommodate various vehicle requirements.[18][19] Although GM announced in October 2024 the discontinuation of the "Ultium" branding for its EV batteries to reflect a multi-chemistry strategy, the underlying modular architecture continues.[10] In 2025, General Motors announced an evolution to lithium manganese-rich (LMR) cathodes in partnership with LG Energy Solution, aiming to lower costs through reduced reliance on scarce materials like nickel and cobalt while improving thermal stability.[8] These LMR cells, planned for prismatic formats in commercial production by 2028, target 33% higher energy density relative to leading lithium iron phosphate (LFP) alternatives, supporting longer-range trucks and SUVs without compromising affordability.[21] This shift builds on the modular pouch stacking of Ultium, allowing seamless integration of diverse chemistries within the same platform. An upcoming LFP variant is slated for production starting in late 2027 at the Ultium Cells facility in Spring Hill, Tennessee, targeting entry-level electric vehicles with enhanced safety profiles and longer cycle life, though at a lower energy density of around 160 Wh/kg.[7][22] LFP's iron-based cathode eliminates cobalt entirely, promoting sustainability and cost efficiency for mass-market adoption.[23] Key innovations in Ultium include the development of silicon-dominant anodes through collaborations like that with OneD Battery Sciences, which fuse silicon nanowires into graphite structures to deliver a 10-15% increase in capacity by leveraging silicon's higher lithium storage potential.[24] Additionally, the platform features an industry-first wireless battery management system (wBMS), co-developed with Analog Devices, that enables real-time monitoring and cell balancing via wireless communication, eliminating nearly 90% of traditional wiring for reduced weight and complexity.[25][26]Specifications and Performance
Ultium battery packs offer scalable energy capacities ranging from 50 kWh to 200 kWh, enabling EPA-estimated driving ranges of 200 to over 400 miles in passenger vehicles and up to over 490 miles in certain configurations, such as the 2025 Chevrolet Silverado EV, depending on vehicle weight, aerodynamics, and efficiency.[27][9] These packs support DC fast charging at rates up to 350 kW in 800-volt architectures, such as those used in heavy-duty trucks and SUVs, allowing the addition of approximately 100 miles of range in 10 minutes under optimal conditions.[28] Advanced thermal management systems ensure safe operation during high-power charging, enabling a charge from 10% to 80% in approximately 40 minutes for models like the Cadillac LYRIQ, based on real-world tests.[29] Ultium batteries target a lifespan of up to 1 million miles or over 1,000 full charge cycles as a development goal, with degradation limited to less than 20% capacity loss, supporting long-term durability for fleet and consumer applications.[30][31] The platform includes variants tailored to different needs, such as nickel-cobalt-manganese-aluminum (NCMA) chemistry for high energy density in premium vehicles. Lithium manganese-rich (LMR) cells, developed in partnership with LG Energy Solution, are projected to achieve 33% higher energy density than lithium iron phosphate (LFP) options by the late 2020s, targeting applications in trucks and SUVs. LFP cells, aimed at cost-sensitive entry-level models, provide approximately 160 Wh/kg at the cell level for balanced performance and affordability.[32][33]Modular Design and Assembly
The Ultium battery platform employs a modular architecture centered on identical large-format pouch cells, each measuring approximately 580 mm in length and 115 mm in height with a thickness of about 10 mm, allowing for scalable stacking in series and parallel configurations to accommodate varying vehicle sizes and power requirements.[34][19] This design enables the assembly of battery packs ranging from compact setups for smaller vehicles to larger arrays for trucks and SUVs, promoting flexibility across General Motors' electric vehicle lineup.[27] In pack construction, the cells are organized into cell module assemblies (CMAs), with each module typically containing 24 cells grouped for serviceability and efficiency, incorporating integrated liquid cooling systems to maintain optimal thermal performance during operation.[34] These modules are then combined into full packs through automated processes that emphasize precision and scalability, reducing complexity in wiring and assembly compared to traditional battery designs.[35] Customization is achieved through adaptable orientations, where cells can be stacked vertically for higher-ground-clearance vehicles like SUVs and trucks or horizontally for sedans and lower-profile models, optimizing space utilization and vehicle dynamics.[36] Additionally, the platform supports software-defined configurations via General Motors' Ultifi system, which allows over-the-air (OTA) updates to adjust battery management parameters and enhance performance without hardware changes.[37][38] Safety features are integrated at the module and pack levels, including molded intumescent materials that expand under heat to contain potential fires and robust housings designed to withstand impacts while complying with global standards such as UN 38.3 for transportation and ISO 26262 for functional safety.[39] This modularity contributes to extended vehicle range, with configurations supporting up to over 490 miles on a single charge in certain applications.[9]Propulsion and Drive System
Traction Motors
The GM EV propulsion architecture (formerly branded as Ultium) primarily employs permanent magnet synchronous motors (PMSMs) for its primary propulsion needs, featuring designs that minimize reliance on heavy rare-earth materials to reduce costs and supply chain risks.[40][41] These motors include a 180 kW front-drive variant and a more powerful 255 kW unit configurable for front or rear axles, enabling high-performance applications.[40] For all-wheel-drive configurations, dual-motor setups combine these PMSMs, as seen in vehicles delivering up to 1,000 horsepower, such as the GMC Hummer EV.[40][42] These oil-cooled motors achieve peak efficiencies exceeding 95%, with some configurations reaching around 97%, thanks to optimized copper windings and stators cooled by modified transmission fluid for sustained high-output operation.[43][41] The oil-cooling system supports high power density, allowing compact designs that enhance vehicle packaging and performance.[28] Complementing the PMSMs, the architecture incorporates magnet-free induction motors, such as the 62 kW all-wheel-drive assist unit, for rear-wheel-drive base models to further lower material costs without compromising core functionality.[41][44] Regenerative braking integration in these motors enables energy recovery during deceleration, feeding power back into the system for improved overall efficiency.[45] These motors pair seamlessly with GM's EV batteries to deliver precise power management.[42] In 2025 updates, traction motors in off-road vehicles like the Hummer EV feature enhanced torque vectoring via the Performance e4WD system, which independently controls power to each wheel for superior traction and maneuverability on challenging terrain. The system is compatible with evolving battery technologies, such as lithium manganese-rich (LMR) cells, for improved performance in trucks and SUVs.[46][47][8]Drive Units and Integration
The EV drive units represent a modular propulsion architecture developed by General Motors, integrating the electric motor, power inverter, and single-speed transmission into a single compact housing that resembles a traditional engine and transmission assembly. This design achieves a significant reduction in parts count and mass, with the integrated power electronics alone cutting mass and volume by nearly 50% compared to previous GM EV generations, facilitating easier manufacturing and improved packaging efficiency.[48][49] At the core of these units are advanced power electronics featuring silicon carbide (SiC) inverters, supporting architectures from 400V to 800V for propulsion and high-voltage charging operations. The SiC technology enables faster switching speeds and higher thermal efficiency, contributing to overall system improvements such as extended vehicle range, reduced weight, and more compact designs without specifying exact percentage gains. This integration is supplied through a partnership with Wolfspeed, ensuring domestically sourced components for GM EV vehicles.[50] The drive system incorporates a unified software platform that manages torque vectoring and distribution across front, rear, or all-wheel configurations, optimizing performance and traction in real time. It also supports one-pedal driving through regenerative braking, allowing deceleration and stopping primarily via the accelerator pedal, and is compatible with vehicle-to-home (V2H) functionality for bidirectional energy flow, with full implementation planned across GM EVs by 2026.[42][51][52] Scalability is a key feature, with five interchangeable drive unit variants enabling single-motor setups for rear-wheel drive efficiency, dual-motor arrangements for all-wheel drive balance, or triple-motor configurations for enhanced performance, all drawing from a shared family of three motor types to support diverse vehicle applications.[53][42]Production and Manufacturing
Facilities and Capacity
Ultium Cells, the joint venture between General Motors and LG Energy Solution, operates primary manufacturing facilities in the United States, with key sites in Warren, Ohio; Spring Hill, Tennessee; and Lansing, Michigan. The Warren, Ohio plant, which opened in 2022, has an annual production capacity of 35 GWh for lithium-ion battery cells. The Spring Hill, Tennessee facility, operational since 2024, targets an annual capacity of 50 GWh following expansions completed in 2025. The Lansing, Michigan plant, under construction since 2022, was fully acquired by LG Energy Solution in early 2025 following GM's sale of its stake, and is designed for 50 GWh annual capacity, with mass production beginning in spring 2025 and operational as of November 2025. Internationally, Ultium Cells sources components from LG Energy Solution's facilities, including a plant in South Korea with supporting capacity for Ultium battery production and an expanded site in Wroclaw, Poland, with a current capacity of 86 GWh as of November 2025 to supply European Ultium applications, planned to reach 115 GWh in coming years.[54]| Facility Location | Annual Capacity (GWh) | Status as of November 2025 |
|---|---|---|
| Warren, Ohio, USA | 35 | Operational, paused until mid-2026 for upgrades |
| Spring Hill, Tennessee, USA | 50 | Operational, paused until mid-2026 for upgrades |
| Lansing, Michigan, USA | 50 | Mass production starting spring 2025, operational |
| Wroclaw, Poland | 86 | Operational, supplying Ultium components; planned expansion to 115 GWh |
| South Korea (LGES support) | Variable (JV supply) | Operational, supporting global Ultium output |