Towards optimal 3D battery electrode architecture: Integrating
This review explores the influence of electrode structural factors on mass transport properties, with a specific focus on the latest developments in three-dimensional (3D) battery
The development of autonomous and stand-alone electronics with a small footprint size has prompted an increasing demand for high-performance energy-storage devices, with rechargeable three-dimensional (3D) batteries being one of these ideal energy devices.
Lithium batteries have become indispensable in energy storage because of their high energy density and extended cycle life. However, the ever-increasing demand highlights several challenges, including insufficient energy and power densities, limited cycle life, and operational safety concerns.
The evolution of energy storage devices, driven by the ever-increasing consumer demand for longer lasting battery life for portable electronics, longer drivable distances with electric vehicles, and sustainable energy solutions, has brought lithium-ion batteries (LIBs) to the forefront of modern energy systems.
Besides experimental studies, simulation modeling and analysis is another important approach to optimize the battery design and understand the electrochemical uniqueness of 3D batte-ries, such as construction principle, current and voltage distribution, and structure stability and evolution.
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