Nanostructured Electrodes for High-Performance Supercapacitors and Batteries

© 2022 by the authors; CC BY-NC-ND license

Si; MnO₂; rGO; sea urchin-like structure; lithium-ion battery; high performance; silica-based anode; Ketjen Black; electrochemical properties; lithium-ion battery; pseudocapacitor; carbon nanotube; polyaniline; fractional-order circuit model; memory effect; fractional derivative; zinc-ion batteries; conducting polymers; polyaniline; zinc-ion diffusion; polyaniline; metal–organic framework; supercapacitors; energy density; specific capacitance; stability; self-powered; wearable flexible sensor; energy harvesting; human motion monitoring; triboelectric nanogenerator; supercapacitors; NiMoO₄@MnCo₂O₄; microstructure; electrochemical performance; cycling stability; semiconductor superlattice; dielectric capacity; energy storage; first-principles calculation; supercapacitor; organic crosslinked polymer; porous carbon; electrochemistry; α-Fe₂O₃@MnO₂; electrode materials; electrochemical performance; flexibility; hydrogen generation; porous titanium oxide cage; PtNi nanoparticles; sodium borohydride hydrolysis; NaBH₄; graphene oxide; catalytic activity; hydrolysis; aqueous zinc ion battery; transition metal chalcogenides; layered structure; cathode; energy storage mechanism; g-C₃N₄; perovskite solar cells; additive; surface modifier layer; Li-rich cathode material; lithium-ion battery; voltage and capacity fade; testing mode; supercapacitor; cobalt-containing nanomaterials; morphological design; bio-derived hard carbon; Coulomb efficiency; Na-ion batteries; storage mechanism; fibrous phosphorus; lithium-Ion battery; anode; CuMn₂O₄; nanosheet arrays; hydrothermal; battery-type; supercapacitors; CoO@rGO; graphene; MOF; flexible electrodes; hollow structure; ultrafast integration; lithium-ion batteries; proton exchange membrane fuel cell; mechanical vibration; durability; platinum migration; accelerated stress test; n/a