Conversion/alloying materials (CAMs) represent a potential alternative to graphite as a Li-
ion anode active material, especially for high-power applications. So far, however …

The energy efficiency of new lithium-ion chemistries is a very important, but frequently not
provided performance measure for new alternative active materials for application as …

Traditional lithium‐ion battery (LIB) anodes, whether intercalation‐type like graphite or
alloying‐type like silicon, which employ a single lithium storage mechanism, are often …

Conversion-alloying-type compounds offer many new possibilities as anode materials for Li-
ion cells, but also show some drawbacks related to their intrinsic characteristics. To …

Recently, printing techniques are increasingly investigated in the field of energy storage,
especially for the fabrication of custom‐designed batteries. Thanks to its many advantages …

To complement or outperform lithium-ion batteries with liquid electrolyte as energy storage
devices, a high-energy as well as high-power anode material must be used in solid-state …

Conversion/alloy active materials, such as ZnO, are one of the most promising candidates to
replace graphite anodes in lithium-ion batteries. Besides a high specific capacity (q ZnO …

High-capacity lithium-ion anodes such as alloying-, conversion-, and conversion/alloying-
type materials are subjected to extensive volume variation upon lithiation/delithiation …

Lithium-ion batteries have achieved great improvement in the past decades, while high-
performance anode materials are still challenging. Metal do**, vacancy generation, and …

The introduction of transition metal dopants such as Fe and Co in zinc oxide enables
substantially enhanced reversible capacities and greater reversibility of the de-/lithiation …