SiOx anode with higher specific capacity than graphite and better capacity retention than
pure Si has received great attention from both academia and the industry. However, the …

Nowadays, lithium-ion batteries are one of the most widespread energy storage systems,
being extensively employed in a large variety of applications. A significant effort has been …

SiO x negative electrodes for Li-ion batteries enable high energy density while providing
better structural integrity compared to pure Si electrodes. The oxygen content has a critical …

SiOx is a promising next‐generation anode material for lithium‐ion batteries. However, its
commercial adoption faces challenges such as low electrical conductivity, large volume …

Failure mechanisms associated with silicon‐based anodes are limiting the implementation
of high‐capacity lithium‐ion batteries. Understanding the aging mechanism that deteriorates …

Silicon (Si) is a promising anode material for lithium-ion batteries but has long been
suffering from low conductivity, drastic volume change, poor cycling performance, etc …

The high-capacity silicon oxide (SiO x) is a promising anode candidate for lithium-ion
batteries (LIBs), but the huge volume expansion during the cycle severely limits their …

Silicon suboxides (SiO x) have achieved partial success in commercialization as high-
capacity anode materials to replace graphite because of optimal electrochemical properties …

SiO is a promising negative electrode material to increase Li-ion batteries specific energy
thanks to its high capacity and stability. However it needs to be blended in low amounts with …

Multilayer graphene is prepared by micromechanical exfoliation method. Then, it is used as
conductive component for lithium ion battery SiO x anodes. Uniform SiO x/graphene …