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Intellectual Property Office

Carbon and Metal Dual Buffer Layer to Suppress Lithium Dendrite Growth in Solid-State Batteries 2025-047

Applications

  • EV batteries and charging
  • Use in anode systems of solid-state batteries

Advantages/Benefits

  • Significantly improves Li plating and stripping cycles
  • Extends cycle life
  • Low cost and scalable materials 
  • Can be used in an anode free configuration

Background 

All-solid-state lithium-metal batteries hold great promise because of their high energy density. However, lithium dendrite growth occurs during charging and poses a risk to battery safety and performance. There is a need for technologies to mitigate this issue.

Technology Overview

Scientists at Berkeley Lab have developed a dual buffer layer (BL) composed of tin (Sn) nanoparticles and carbon, on a current collector to suppress lithium dendrite growth towards a solid electrolyte. Key features of this technology include:

  • The use of direct current (DC) magnetron sputter coating to deposit tin and carbon onto a current collector to achieve uniform lithium-metal plating and improved cycle performance. 
  • A dual buffer layer (BL) of Sn-C, where a thin C layer is deposited onto a Sn metal layer. 
  • The Sn results in a uniform lithium-metal deposition onto the current collector, while the C prevents lithium dendrite growth towards the solid electrolyte. 

The Sn–C buffer layer shows stable Li-plating/stripping cycling over 450 cycles without noticeable short-circuit. Optical and electron microscopy analysis have confirmed the successful role of the Sn-C BL. 

Development Stage

TRL 3 – Analytical and experimental critical function and/or characteristic proof of concept

For More Information

Avvaru, V. (2025). Tin-Carbon Dual Buffer Layer to Suppress Lithium Dendrite Growth in All-Solid-State Batteries. ACS Nano, Vol. 9 (Issue 18), 17347-17356. https://doi.org/10.1021/acsnano.4c16271

Principal Investigator(s)

  • Haegyum Kim

Status

Patent pending

Opportunities

Available for licensing or collaborative research

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Stable and high performing polymer composite electrolytes for solid-state batteries

Cathode active material coating on carbon framework for solid-state batteries with improved performance