Physics-based electrochemical battery models derived from porous electrode theory are a
very powerful tool for understanding lithium-ion batteries, as well as for improving their …

As the UK battery modelling community grows, there is a clear need for software that uses
modern software engineering techniques to facilitate cross-institutional collaboration and …

Hundreds of millions of people lack access to electricity. Decentralized solar-battery systems
are key for addressing this while avoiding carbon emissions and air pollution but are …

New experimental technology and theoretical approaches have advanced battery research
across length scales ranging from the molecular to the macroscopic. Direct observations of …

A complete set of thermodynamic and mass-transport properties is determined for solutions
of LiPF 6 in propylene carbonate at 25° C, elucidating the composition dependences of six …

We propose algorithms to speed up physics-based battery lifetime simulations by one to two
orders of magnitude compared to the state-of-the-art. First, we propose a reformulation of the …

Differential voltage analysis (DVA) is a conventional approach for estimating capacity
degradation in batteries. During charging, a graphite electrode goes through several phase …

Electrochemical and equivalent-circuit modeling are the two most popular approaches to
battery simulation, but the former is computationally expensive and the latter provides limited …

Solar home systems (SHS) provide low-cost electricity access for rural off-grid communities.
Batteries are a crucial part of the system, however they are often the first point of failure due …

A vast majority of human population around the planet has limited availability to electricity.
Inexpensive energy storage systems are crucial for solving this critical issue. Rapid rise in …