Results 201 to 210 of about 748,119 (287)

Nanosized Li₂S-Loaded Polar Porous Carbon Nanofibers as Self-Supporting Electrodes in Anode-Free Lithium-Sulfur Batteries. [PDF]

Adv Sci (Weinh)
Feng P, Wu Q, Xu Y, Lu L, Zheng T, Xu T, Xu W, Höche D, Kochovski Z, Lu Y.   +9 more
europepmc   +1 more source

“Dead Lithium” Formation and Mitigation Strategies in Anode‐Free Li‐Metal Batteries

Batteries &Supercaps, Volume 8, Issue 3, March 2025.
Anode‐free lithium metal batteries, though promising due to their high energy density, face challenges from dead lithium formation. “Dead lithium”, disconnected from the anode, causes capacity loss, increased resistance, and safety risks. This review explores the origins of dead lithium, its impact on battery performance, and potential strategies for ...
Mozaffar Abdollahifar, Andrea Paolella
wiley   +1 more source

2,5-Dimercapto-1,3,4-thiadiazole-modified gel electrolyte for reduced shuttle effect and enhanced redox kinetics of lithium-sulfur batteries. [PDF]

RSC Adv
Lin X, Wang J, Tang X, Yang M, Chen N, Li F, Zhang F.   +6 more
europepmc   +1 more source

Elucidating Reversible Electrochemical Redox of Li6PS5CI Solid Electrolyte [PDF]

, 2019
Banerjee, Abhik, Chen, Zheng, Doux, Jean-Marie, Marple, Maxwell AT, Meng, Ying Shirley, Nguyen, Han, Tan, Darren HS, Wang, Xuefeng, Wu, Erik A, Yang, Hedi   +9 more
core  

Modification of the Solid Electrolyte Interphase on SiGr Electrodes by a Prelithiation Method Using Passivated Lithium Metal Powder

Batteries &Supercaps, EarlyView.
Prelithiation of SiGr electrodes by direct contact with passivated lithium metal. powder creates a solid electrolyte interphase (SEI) layer prior to cycling which is superior to the one conventional SEI layer produced during the formation cycles in nonprelithiated cells.
Ekin Esen, Iratxe de Meatza, Martin Schmuck, Mohsen Padervand, Martin Winter, Elie Paillard, Masoud Baghernejad   +6 more
wiley   +1 more source

Exploring the Effects of the Spatial Distribution of Catalytic Sites on Sulfur Nucleation Behaviors and Electrochemical Performances of Lithium-Sulfur Batteries. [PDF]

Adv Sci (Weinh)
Kim SY, Cho H, Kim SJ, Ahn M, Jeoun Y, Kim K, Cho SP, Kim SH, Son GY, Yu SH, Hong BH, Sung YE.   +11 more
europepmc   +1 more source

A Sustainable and Low‐Cost Zn‐Lignosulfonate Redox Flow Battery

Batteries &Supercaps, EarlyView.
A cost‐effective Zn/lignosulfonate (NaLS) hybrid flow battery using 20 kDa NaLS delivers 3.52 Ah L−1 at 30 mM, with an average discharge voltage of 1.01 V, outperforming smaller NaLS. This sustainable design leverages industrial and bio‐based lignosulfonates, cheaper size exclusion membrane, and abundant Zn for ecofriendly, scalable energy storage ...
Athul Seshadri Ramanujam, Paula Navalpotro, Nagaraj Patil, Rebeca Marcilla   +3 more
wiley   +1 more source

Designing Moderately-Solvating Electrolytes for High-Performance Lithium-Sulfur Batteries. [PDF]

Adv Mater
Kautz DJ, Cao X, Gao P, Feng S, Zhao Q, Parab S, Xu Y, Quinn JP, Rahman MM, Tan S, Zhang X, Ketabi S, Nazir A, Wang J, Dai F, Wang S, Lu D, Hu E, Meng YS, Wang C, Liu J, Zhang JG, Xu W.   +22 more
europepmc   +1 more source

Na5FeS4 as High‐Capacity Positive Electrode Active Material for All‐Solid‐State Sodium Batteries

Batteries &Supercaps, EarlyView.
All‐solid‐state sodium cells using Na5FeS4, synthesize through a simple and scalable process using sodium polysulfides, as a positive electrode active material exhibit a high reversible capacity of 480 mAh g−¹, which is attributed to the sufficiently high ionic conductivity of the active material and the maintenance of the active material/solid ...
Yuta Doi, Tomoya Otono, Yushi Fujita, Raku Kato, Masato Torii, Jiong Ding, Shigeo Mori, Kota Motohashi, Atsushi Sakuda, Akitoshi Hayashi   +9 more
wiley   +1 more source

Stabilising graphite anode with quasi-solid-state electrolyte for long-life lithium-sulfur batteries. [PDF]

MRS Energy Sustain
Li Z, Yang ZJ, Chhowalla M.
europepmc   +1 more source