TS-074050 — As batteries are pushed toward faster charging and higher power operation, conventional electrode architectures struggle to deliver their full theoretical capacity. Dense electrodes often suffer from poor ion and electron transport, leading to large capacity losses at high charge and discharge rat…

TS-073403 — The rapid growth of electric vehicles and energy storage systems is driving an unprecedented volume of end‑of‑life lithium‑ion batteries, creating both environmental and supply‑chain challenges. Conventional recycling routes focus on metal recovery through energy‑intensive processes and …

TS-072842 — The energy density and safety of lithium-metal solid-state batteries (LIMSSBs) are limited by the stability of the interface between the lithium-metal anode and the solid-state electrolyte. Traditional approaches using static interlayers or coatings often fail to maintain continuous contact during…

TS-072330 — The Need Current solid-state batteries (SSBs) offer high energy density and improved safety but require high stack pressures for stable operation, limiting their practicality in electric vehicles and consumer electronics. Silicon anodes, while promising for their high capacity, suffer from rapid deg…

TS-070308 — The Need Current lithium iron phosphate (LFP) cathode materials suffer from poor electronic conductivity and limited lithium-ion diffusion, especially under high-rate charging conditions. These limitations hinder the performance of lithium-ion batteries (LiBs) in demanding applications such as elect…

TS-066056 — The Need The advancement of lithium-ion battery technology relies heavily on increasing energy density, yet practical usage of silicon (Si) anodes faces challenges due to parasitic side reactions and active lithium consumption. Controlling lithium amounts precisely while achieving uniform distribut…

TS-066037 — The Need In the realm of materials science and energy storage, there's a growing demand for innovative anode synthesis methods that yield materials with improved mechanical and electrochemical properties. Traditional synthesis techniques often fall short in achieving the desired performance met…

TS-066015 — The Need Over the past two decades, the advancement of metal-O2 batteries has been hindered by issues of instability, reversibility, and poor energy efficiency, primarily due to the instability of superoxide in the presence of Li+ and Na+ ions. Existing solutions such as Li-O2 and Na-O2 batteries h…

TS-064150 — The Need As the global demand for energy storage devices continues to surge, the limitations of conventional lithium-ion batteries become increasingly evident. Dwindling lithium reserves are unable to meet the burgeoning needs of modern society, necessitating the exploration of alternative solution…

TS-063224 — The Need In the rapidly evolving landscape of electric vehicle (EV) technology, there exists a pressing commercial need for rechargeable lithium-ion batteries (LiBs) that can not only deliver high charge capacities and power densities but also address the critical issues of capacity fading and safe…