Summary
- Amprius Technologies shipped a new 6.3 Ah SiCore cell to an unnamed Fortune 500 customer in the light electric vehicle segment
- The battery is designed for applications requiring efficient energy storage solutions, including fixed-wing aviation and robotics
- The SiCore cell offers a specific energy of 315 Wh/kg and a high-power 3C discharge rate, with capacity exceeding a standard cell by 25%
- The battery is capable of 800 cycles at 80% depth of discharge, extending lifespan and reducing replacement costs
- Amprius, based in California, recently announced an expanded contract manufacturing agreement to meet growing demand for high-performance silicon batteries
Article
Amprius Technologies, a manufacturer of lithium-ion batteries utilizing silicon anode technology, has introduced its new 6.3 Ah SiCore cell to a Fortune 500 customer in the light electric vehicle industry. The company aims to provide more efficient energy storage solutions for various applications such as fixed-wing aviation, robotics, and the EV market. The SiCore cell offers drop-in compatibility, delivering a specific energy of 315 Wh/kg, over 25% more capacity than a standard 5.0 Ah 21700 cell, and maintains a high-power 3C discharge rate. Amprius also claims the cell can achieve 800 cycles at 80% depth of discharge, extending battery lifespan and reducing replacement costs.
Dr. Ionel Stefan, Amprius’ CTO, reports strong interest from leading OEM manufacturers due to the significant improvement in battery performance the new cell provides. Founded in 2008 and based in Fremont, California, Amprius operates a research and development laboratory and a MWh-scale manufacturing facility for silicon anodes and cells in addition to its headquarters. The company recently announced an expanded contract manufacturing agreement to meet the growing demand for high-performance silicon batteries required in advanced electric mobility applications. CEO Kang Sun mentioned the need for gigawatt-hour-scale production capacity to fulfill the requirements of their customers.
The SiCore cell by Amprius Technologies offers a more efficient energy storage solution for applications such as fixed-wing aviation, robotics, and the EV market. With drop-in compatibility and a specific energy of 315 Wh/kg, the cell provides over 25% more capacity than standard cells while maintaining a high-power 3C discharge rate. Amprius states that the cell can achieve 800 cycles at 80% depth of discharge, extending battery lifespan and reducing replacement costs. The company’s CTO, Dr. Ionel Stefan, noted the strong interest from leading OEM manufacturers in the enhanced battery performance the new cell delivers.
Amprius Technologies, a manufacturer of lithium-ion batteries utilizing silicon anode technology, has launched its new 6.3 Ah SiCore cell, catering to customers in the light electric vehicle segment, including a member of the Fortune 500 list. The company is focused on providing efficient energy storage solutions for various applications, mentioning fixed-wing aviation, robotics, and the EV market as potential markets for the new cell. With specific energy of 315 Wh/kg, the cell offers drop-in compatibility, over 25% more capacity than standard cells, and a high-power 3C discharge rate. Amprius also claims the cell can achieve 800 cycles at 80% depth of discharge, enhancing battery lifespan and reducing replacement costs.
Founded in 2008 and headquartered in Fremont, California, Amprius Technologies operates a research and development laboratory and a MWh-scale manufacturing facility for silicon anodes and cells, supporting its aim to deliver high-performance silicon batteries for advanced electric mobility applications. CEO Kang Sun mentioned the necessity for gigawatt-hour-scale production capacity to meet the demands of their customers. The company recently announced an expanded contract manufacturing agreement to ensure the availability of high-performance silicon batteries and meet the growing requirements of the EV market and other sectors requiring energy storage solutions.
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