Neutron diffraction for revealing the structures and ionic transport mechanisms of antiperovskite solid electrolytes

“…It is worth noting that the battery assembled with FePS 3 electrodes exhibited fast charge and discharge characteristics without the need for solid electrolyte and conductive additives, suggesting that FePS 3 offers sufficient lithium ion and electron conduction pathways. [127][128][129][130] During the charge and discharge processes, a reversible redox reaction (FePS 3 + x Li + + x e − ⇄ Li x FePS 3 , 0 ≤ x ≤ 1.5) occurs, and the discharge voltage increases as the chemical state of iron and sulfide evolves.…”

Metal Phosphorous Chalcogenide: A Promising Material for Advanced Energy Storage Systems

“…It is worth noting that the battery assembled with FePS 3 electrodes exhibited fast charge and discharge characteristics without the need for solid electrolyte and conductive additives, suggesting that FePS 3 offers sufficient lithium ion and electron conduction pathways. [127][128][129][130] During the charge and discharge processes, a reversible redox reaction (FePS 3 + x Li + + x e − ⇄ Li x FePS 3 , 0 ≤ x ≤ 1.5) occurs, and the discharge voltage increases as the chemical state of iron and sulfide evolves.…”

Metal Phosphorous Chalcogenide: A Promising Material for Advanced Energy Storage Systems

Antiperovskite active materials for metal-ion batteries: Expected advantages, limitations, and perspectives

Toward high performance all-solid-state lithium or sodium metal batteries: Potential application on Li/Na-rich antiperovskites (LiRAPs/NaRAPs) electrolyte for energy storage