Results 81 to 90 of about 24,168 (208)

Enabling Thin and Flexible Solid-State Composite Electrolytes by the Scalable Solution Process [PDF]

, 2019
All solid-state batteries (ASSBs) have the potential to deliver higher energy densities, wider operating temperature range, and improved safety compared with today's liquid-electrolyte-based batteries. However, of the various solid-state electrolyte (SSE)
Banerjee, A, Chen, Z, Cheng, JH, Deng, Z, Doux, JM, Meng, YS, Nguyen, H, Ong, SP, Tan, DHS, Wang, X, Wu, EA   +10 more
core  

Metal‐free two‐dimensional phosphorene‐based electrocatalyst with covalent P–N heterointerfacial reconstruction for electrolyte‐lean lithium–sulfur batteries

Carbon Energy
The use of lithium–sulfur batteries under high sulfur loading and low electrolyte concentrations is severely restricted by the detrimental shuttling behavior of polysulfides and the sluggish kinetics in redox processes.
Jiangqi Zhou, Chengyong Shu, Jiawu Cui, Chengxin Peng, Yong Liu, Weibo Hua, Laura Simonelli, Yuping Wu, Shi Xue Dou, Wei Tang   +9 more
doaj   +1 more source

Scalable Freeze-Tape-Casting Fabrication and Pore Structure Analysis of 3D LLZO Solid-State Electrolytes. [PDF]

, 2020
Nonflammable solid-state electrolytes can potentially address the reliability and energy density limitations of lithium-ion batteries. Garnet-structured oxides such as Li7La3Zr2O12 (LLZO) are some of the most promising candidates for solid-state devices.
Chen, Guoying, Chen, Kai, Doeff, Marca M, Heywood, Stephen, Parkinson, Dilworth Y, Shen, Hao, Sofie, Stephen, Tamura, Nobumichi, Yi, Eongyu   +8 more
core  

Fabrication of NiFe-LDHs Modified Carbon Nanotubes as the High-Performance Sulfur Host for Lithium–Sulfur Batteries

Nanomaterials
Lithium–sulfur batteries offer the potential for significantly higher energy density and cost-effectiveness. However, their progress has been hindered by challenges such as the “shuttle effect” caused by lithium polysulfides and the volume expansion of ...
Lingwei Zhang, Runlan Li, Wenbo Yue
doaj   +1 more source

Enhancing Lithium-Sulfur Battery Performance by MXene, Graphene, and Ionic Liquids: A DFT Investigation. [PDF]

Molecules, 2023
Cao J, Xue S, Zhang J, Ren X, Gao L, Ma T, Liu A.   +6 more
europepmc   +1 more source

Boosting Lean Electrolyte Lithium-Sulfur Battery Performance with Transition Metals: A Comprehensive Review. [PDF]

Nanomicro Lett, 2023
Pan H, Cheng Z, Zhou Z, Xie S, Zhang W, Han N, Guo W, Fransaer J, Luo J, Cabot A, Wübbenhorst M.   +10 more
europepmc   +1 more source

High temperature storage characteristics of lithium sulfur dioxide cells [PDF]

Hermetically sealed SO2 cells were developed to eliminate SO2 diffusion and its adverse effects on shelf life. A two part barrier coating material was applied to the internal surface of the glass seal and cured under a predetermined thermal profile in ...
Watson, T.
core   +1 more source

Construction of Polypyrrole-Coated CoSe₂ Composite Material for Lithium-Sulfur Battery. [PDF]

Nanomaterials (Basel), 2023
Wu Y, Feng Y, Qiu X, Ren F, Cen J, Chong Q, Tian Y, Yang W.   +7 more
europepmc   +1 more source

Polyaniline-Coated Porous Vanadium Nitride Microrods for Enhanced Performance of a Lithium-Sulfur Battery. [PDF]

Molecules, 2023
Lv J, Ren H, Cheng Z, Joo SW, Huang J.
europepmc   +1 more source

Lithium cell technology and safety report of the Tri-Service Lithium Safety Committee [PDF]

The organization of the Tri-Service Lithium Safety Committee is described. The following areas concerning lithium batteries are discussed: transportation--DOT Exemption 7052, FAA; disposal; storage; individual testing/test results; and battery design and
Reiss, E.
core   +1 more source