Jake Christensen

TL;DR: In this paper, the authors discuss the most critical challenges to developing robust, high-energy Li/air batteries and suggest future research directions to understand and overcome these challenges and predict that Li-air batteries will primarily remain a research topic for the next several years.

TL;DR: In this paper, the authors present a detailed description and model of a Li-ion battery, which is based on using electrochemical principles to develop a physics-based model in contrast to equivalent circuit models.

TL;DR: In this article, the authors present a physics-based model that incorporates the major thermodynamic, transport, and kinetic processes of the Li/oxygen battery, and obtain a good match between porous-electrode experiments and simulations by using an empirical fit to the resistance of the discharge products (which include carbonates and oxides when using carbonate solvents) as a function of thickness.

TL;DR: This work proposes an output error injection observer based on a reduced set of partial differential-algebraic equations that has a less complex structure, while it still captures the main dynamics of a lithium-ion battery.

TL;DR: The chemically and mechanically stable hybrid LiF/h-BN film successfully suppresses lithium dendrite formation during both the initial electrochemical deposition onto a copper foil and the subsequent cycling.