Results 191 to 200 of about 91,322 (303)

Symmetric molecular design: Stable lithium metal batteries. [PDF]

Innovation (Camb)
Ding H, Li X.
europepmc   +1 more source

An Advanced High‐Performance Ultrafast Ammonium‐Ion Aqueous Battery Based on Dual‐Metal Redox Open Framework Molecular Magnet

Advanced Science, EarlyView.
The Prussian Blue Analogue molecular magnet KMnFeHCF is demonstrated as a high‐performance cathode for ultra‐fast aqueous ammonium‐ion batteries. A full cell using KMnFeHCF and graphite delivers ~71 mAh g−1 at 1.25 A g−1 and ~51 mAh g−1 at 2.2 A g−1, retaining 50% capacity after 1850 cycles. Its scalability, cycling stability, and low cost offer strong
Nilasha Maiti, Pramod Bhatt, Manoj K Sharma, Sher Singh Meena, Mayuresh D Mukadam, Soumen Samanta   +5 more
wiley   +1 more source

Flame-retardant electrolytes with electrochemically-inert and weakly coordinating dichloroalkane diluents for practical lithium metal batteries. [PDF]

Nat Commun
Wang Z, Tu H, Ma X, Lu S, Su G, Gao Y, Xue J, Liu L, Yao X, Liang K, Wang K, Zhang F, Qin Z, Zheng J, Wang Q, Xu J, Chen L, Li H, Wu X.   +18 more
europepmc   +1 more source

Enhancing Cycling Stability of Aqueous Aluminum‐Metal Batteries via LaCl3‐Modulated Interfacial Reactions

Advanced Science, EarlyView.
In the aqueous AlCl3 electrolyte of aluminum‐metal batteries, the introduction of LaCl3 adjusts the solvation structure of Al3+ and enhances its diffusion level. The oxide precipitate formed by La3+ covers the aluminum metal anode and effectively alleviates corrosion reactions, thereby improving the cycling stability of the battery.
Yanshen Gao, Karol Załęski, Emerson Coy, Błażej Scheibe, Kacper Szymański, Qingshan Yang, Ewa Mijowska, Xianjie Liu, Ran Jia, Dariusz Moszyński, Linfeng Hu, Rudolf Holze, Xuecheng Chen   +12 more
wiley   +1 more source

A high-entropy mixed ionic and electronic conductor for accelerating the cathode dynamics in all solid-state lithium metal batteries. [PDF]

Sci Adv
Kong X, Jin Z, Chen L, Huang X, Feng B, Huang H, Xu Y, Wu W, Yang W, Shen S, Zhuo Z, Ping W, Peng R, Chen C, Wang C.   +14 more
europepmc   +1 more source

Mitigating the Rock‐Salt Phase Transformation in Disordered LNMO Through Synergetic Solid‐State AlF3/LiF Modifications

Advanced Science, EarlyView.
The transition between the spinel and rock‐salt phases induces irreversible structural changes in disordered LiNi0.5Mn1.5O4, thereby preventing it from fully releasing its electrochemical capacity during charge/discharge cycling. Abstract High‐voltage disordered spinel LiNi0.5Mn1.5O4 is a promising cathode material for high power density in lithium‐ion
Xingqi Chang, Carlos Escudero, Ashley P Black, Sharona Horta, Elías Martínez, Xuan Lu, Jordi Llorca, Maria Ibáñez, Jordi Jacas Biendicho, Andreu Cabot   +9 more
wiley   +1 more source

A porous tellurium interlayer for high-power and long-cycling garnet-based quasi-solid-state lithium-metal batteries. [PDF]

Nat Commun
Kim JS, Yoon G, Kim YS, Kim TH, Kim S, Kim J, Lee J, Kim R, Lee MJ, Yashiro N, Suzuki S, Asano T, Badding M, Song Z, Heo S.   +14 more
europepmc   +1 more source

Nanodiamond Regulated Electrolyte Enhances Thermal, Chemical and Structural Properties for Highly Reversible Zn Metal Anodes

Advanced Science, EarlyView.
Nanodiamond additives are dispersed in the aqueous electrolyte to organize water molecules, suppress gas evolution and metal corrosion, and guide zinc to deposit more uniformly. Together with enhanced thermal conductivity for fast heat removal, this strategy reduces temperature rise and degradation, enabling safer, more durable rechargeable zinc metal ...
Jiayan Zhu, Xuan Gao, Nan Gao, Shaoheng Cheng, Junsong Liu, Yuhang Dai, Zhengxiao Guo, Hongdong Li   +7 more
wiley   +1 more source

Local crystallization inside the polymer electrolyte for lithium metal batteries observed by operando nanofocus WAXS. [PDF]

Nat Commun
Apfelbeck FAC, Wittmann GE, Le Dû MP, Cheng L, Liang Y, Yan Y, Davydok A, Krywka C, Müller-Buschbaum P.   +8 more
europepmc   +1 more source

Lithium Squarate as Sacrificing Electrolyte Additive for Prelithiation: Case Study in Zero‐Excess Lithium Metal Batteries

Advanced Science, EarlyView.
Active lithium loss (ALL) and capacity fade can be compensated by prelithiation, apparently simple via sacrificing additives e.g., lithium squarates. However, as a cathode additive it ruptures the cathode via gas evolution, while as an electrolyte additive it gets reductively depleted on anode side in course of solid electrolyte interphase (SEI ...
Ibrahim Lawan Abdullahi, Anindityo Arifiadi, Alexandros Tsoufios, Nick Fehlings, Silvan Stuckenberg, Lukas Stolz, Dominik Voigt, Martin Winter, Johannes Kasnatscheew   +8 more
wiley   +1 more source