China
Jiangsu University of Science and Technology
Prussian blue analogues, Vanadium ferrohexanocyanate, Cathode, Sodium ion batteries
Prussian blue analogues, Vanadium ferrohexanocyanate, cathode, Sodium ion batteries
Hard Carbon, Rice husk, Anode, Sodium-ion batteries
SiOx, Rice husk, graphene aerogel, Anode, lithium ion batteries
Carbon, Soft carbon, Hard carbon, Anode, Sodium-ion battery
LiMg0.95Mg0.02Al0.03O2, Li2ZrO3, High-nickel cobalt-free;Cathode, lithium-ion batteries
Porous carbon, Sugarcane bagasse, N, P co-doped, Anode, Supercapacitors, Sodium-ion batteries
FeSe2-Fe2O3, Graphene aerogel, Nanotube, heterointerface, Lithium-ion batteries
Heterointerface engineering, Bimetallic selenides, Sodium-ion batteries, Carbon nanofibers, Electrospinning
Lignin, Petroleum coke, Nanofibers, Anodes, Sodium-ion batteries
SiOx, Attapulgite, Graphene, Anode, Lithium-ion batteries
Metal selenides, Sodium ion batteries, anodes, Graphene, Heterojunction
Transition metal selenide (TMS) is a very promising anode for next-generation high-performance sodium ion batteries (SIBs) because of its high theoretical capacity and rich redox behaviors. However, the disadvantages of poor reaction kinetics and severe ca
CoSe2-FeSe2, N-doped carbon, anode, Metal selenides, sodium ion batteries
Peanut shells, Heteroatom doping, Porous structure, Anode, Sodium-ion batteries
MoS2, Heteroatoms co-doped, electrocatalyst, Overall water splitting
Prussian blue analogues, Cryogenically controlled, Symmetric supercapacitors
Prussian blue analogues, Vanadium ferrohexanocyanate, Graphene, Cathode, Sodium Ion Batteries
Silicon anodes, Colloidal binder, Dual network crosslinking, Interface engineering, Lithium-ion batteries
Silicon anodes, Sustainable binder, Hydrogen bonding, Biomass materials, lithium-ion batteries
