Stanford researchers have developed a mechanistic guideline for lithium metal battery electrolyte and separator design to mitigate lithium dendrite growth.
Stanford researchers have demonstrated a self healing electrode that can dramatically enhance the cycle lifetime of lithium ion batteries by applying Si microparticles with a thin layer of self-healing conductive composite.
Stanford researchers have developed a low cost, safe, environmentally friendly, rechargeable Zn/MnO2 flow battery with the potential for grid scale energy storage.
Stanford researchers have developed a high-performance, ultrafast, thermoresponsive polymer that can act as a circuit breaker to prevent fires in next-generation high-energy-density batteries by rapidly and reversibly turning off when overheated.
Researchers at Stanford University and SLAC National Accelerator Laboratory have developed a new coating design which makes lithium metal batteries stable and promising for further development.
Stanford researchers have developed various high ionic conductivity thin films (LiAlO2, LiAlF4) to stabilize lithium ion battery electrodes without sacrificing power density.
Stanford researchers at the Cui Lab have adopted for the first time, a 3D porous lithium (Li) metal anode and flowable interphase to construct an all-solid-state Li metal battery.
Stanford researchers in Zhenan Bao and Yi Cui's labs have developed an organic redox mediator that could make Lithium Sulfur batteries charge faster with less energy.
Stanford researchers developed a 'self-healing' polymer coating that conforms to and stabilizes lithium metal battery electrodes. The polymer is an extremely stretchy, flexible and adaptive protective layer.