Silicon anodes have been extensively studied as a potential alternative to graphite ones for
Li-ion batteries. However, their commercial application is limited by the issues of the poor …

Alleviating large stress is critical for high‐energy batteries with large volume change upon
cycling, yet this still presents a challenge. Here, a gradient hydrogen‐bonding binder is …

Despite their rapid emergence as the dominant paradigm for electrochemical energy
storage, the full promise of lithium-ion batteries is yet to be fully realized, partly because of …

SiO, comprised of silicon and silicon dioxides (SiO2), is one of the most commercially
promising anode materials to mix with current widely used graphite for the high energy …

Sustainable electrical energy storage is one of the most important scientific endeavors of this
century. Battery and supercapacitor technologies are here crucial, but typically the current …

Hybrid redox flow batteries (RFBs) offer a much higher energy density compared to all-liquid
RFBs. However, the negative electrodes of hybrid RFBs normally utilize metal deposition …

Conspectus In electrochemical energy storage systems, the reversible storage capacity of
battery materials often degrades due to parasitic reactions at the electrode–electrolyte …

Lithium ion (Li-ion) cells have gained considerable attention in the past few years as one of
the most promising energy storage systems for various applications. Binders, an important …

Silicon has been a pivotal negative electrode material for the next generation lithium-ion
batteries due to its superior theoretical capacity. However, commercial application of Si …

Mechanical degradation caused by lithiation/delithiation-induced stress and large volume
change is the primary cause of fast capacity fading of silicon (Si)-based electrodes. Although …