Results 141 to 150 of about 7,444 (215)
A dual‐additive electrolyte strategy is developed to address the hydrolysis of I+ in the aqueous electrolytes. The steric‐hindrance effect of TES− effectively shields I+ from nucleophilic attacks by hydroxyl groups, facilitating the reversible I−/I0/I+ conversion with four‐electron transfer.
Shuai Wang +8 more
wiley +1 more source
Recent Advances of Atomic/Molecular Layer Deposition Engineering Silicon Interface for Lithium-Ion Batteries. [PDF]
Wen H +11 more
europepmc +1 more source
Molecularly engineered self‐assembled monolayers (SAMs) featuring extended conjugated terminals facilitate superior interfacial coupling with the organic solar cell active layer. By physically anchoring the local morphology, this design suppresses thermal degradation, allowing devices to operate at 85°C for 150 h before degrading to 90% of their ...
Gengxin Du +17 more
wiley +1 more source
FeS<sub>2</sub>/CuFeS<sub>2</sub> Composite Anodes Based on Seafloor Massive Sulfides Compositions for Lithium-Ion Batteries. [PDF]
Yan S +5 more
europepmc +1 more source
Polymer electrolytes (PEs) are often indiscriminately grouped as “solid polymer electrolytes (SPEs)”, despite fundamental differences in their ion‐transport mechanisms. This Perspective establishes a mechanism‐based framework that distinguishes gel, quasi‐solid, and all‐solid polymer electrolytes based on their dominant ion‐transport pathways.
Jing Chen +15 more
wiley +1 more source
Halide-Based Solid Electrolytes for Advanced All-Solid-State Batteries: Design, Interfaces, and Electrochemical Performance. [PDF]
Guddehalli Chandrappa S +2 more
europepmc +1 more source
A general, versatile laser‐shock synthesis process is reported to produce various bimetallic CuNi, CuFe, CuCo, and medium‐entropy CuFeCoNi heterostructures, in which crystalline metal nanoparticles are anchored to amorphous hydroxide supports. During nitrate reduction reaction, the heterostructures undergo dynamic amorphous/crystalline reconstruction ...
Weihua Guo +18 more
wiley +1 more source
Impact of Anode to Cathode Crossover in Lithium-metal Batteries With High-Nickel Cathodes. [PDF]
Guo Z, Dolocan A, Manthiram A.
europepmc +1 more source
Engineering CO2 Reduction Pathways via Alloy‐Support Interactions in Li‐CO2 Batteries
Alloy‐support interactions in RuCu/NC induce interfacial charge redistribution and shift d‐band centers, steering CO2 reduction from Li2CO3 to metastable Li2C2O4. This pathway engineering lowers the rate‐determining barrier and suppresses carbonate formation, enabling high discharge voltage (3.23 V) in Li‐CO2 batteries with reduced overpotential (0.50 ...
Liang Sun +8 more
wiley +1 more source
Enhanced lithium storage in silicon anodes <i>via</i> Sn-Ni heterostructures and graphene conductive networks: interface regulation mechanisms. [PDF]
Zhen L +6 more
europepmc +1 more source

