Results 171 to 180 of about 32,885 (283)

Methodological insights into sulfur immobilization techniques on commercial carbon for lithium-sulfur batteries. [PDF]

RSC Adv
Shinkarova Y, Tursynbek M, Kenzhebek M, Tatykayev B, Supiyeva Z, Kerimkul T, Sultanov F, Mentbayeva A.   +7 more
europepmc   +1 more source

Poly(Vinylidene Fluoride)‐Wrapped LiFePO4 Microspheres as Highly Stable Dual Functional Cathode for Solid‐State Lithium Batteries

Advanced Energy and Sustainability Research, EarlyView.
A dual functional cathode is made by uniformly dispersing the cathode material (LiFePO4) into the polymer electrolyte poly(vinylidenfluorid‐co‐hexafluorpropylene):lithium bis(trifluoromethanesulfonyl)imide, resulting in a conformable lamella structure with embedded microspheres.
Taoran Li, Frederik Bettels, Zhihua Lin, Sreeja K. Satheesh, Chaofeng Zhang, Yuping Liu, Fei Ding, Lin Zhang   +7 more
wiley   +1 more source

Revealing the Hidden Electrochemical Pathway for Cathode Electrolyte Interface Formation in Lithium-Sulfur Batteries with Carbonate-Based Electrolytes. [PDF]

ACS Appl Energy Mater
García-Soriano FJ, Jerovsek J, Maldonado-Ochoa SA, Vaca Chávez F, Tarimo DJ, Presser V, Genorio B, Florent M, Bandosz TJ, Dominko R, Prehal C, Vizintin A.   +11 more
europepmc   +1 more source

Layered Ti1‐xFexS2 Cathode Materials with Anionic Redox Chemistry for Mg Storage

Advanced Energy and Sustainability Research, EarlyView.
The predicted layered Ti‐Fe sulfides exhibit joint cationic and anionic redox and faster Mg2+ kinetics over pyrite forms and are promising cathodes for rechargeable Mg battery. Rechargeable magnesium batteries (RMBs) are a promising alternative to lithium‐ion batteries because of the high capacity and crustal abundance of magnesium.
Arup Chakraborty, Haoxiang Wang, Kaijie Yan, Zinuo Xu, Zejing Lin, Chengliang Wang, Liumin Suo, Minglei Mao, Dan T. Major   +8 more
wiley   +1 more source

Size-Selective Nanoporous Atomically Thin Graphene Separators for Lithium-Sulfur Batteries. [PDF]

ACS Appl Mater Interfaces
Gribble DA, Cheng P, Pol VG, Kidambi PR.
europepmc   +1 more source

Low‐Carbon Poly(3‐vinyl‐N‐methylphenothiazine) Electrode Formulation Using PEDOT:PSS (poly(3,4‐ethylenedioxythiophene):poly(styrene sulfonate)) for Lithium‐Based Energy Storage

Advanced Energy and Sustainability Research, EarlyView.
Organic electrode materials typically suffer from low electronic conductivity, requiring large amounts of carbon additives. Herein, a conducting polymer, PEDOT:PSS, is introduced as a partial replacement for carbon black, reducing the carbon content to 15 wt%.
Sathiya Priya Panjalingam, Philipp Penert, Birgit Esser, Martin Winter, Peter Bieker   +4 more
wiley   +1 more source

Lithium-Sulfur Batteries: 3D Printed Tools and Assembly Techniques for Repeatable Lab-Scale Coin Cell Manufacturing. [PDF]

ACS Omega
Miranda D, Aliyev T, Kovacevic L, Voleti S, Lee J, Meehan K, So MC, Dirlam PT.   +7 more
europepmc   +1 more source

What to Make and How to Make It: Combining Machine Learning and Statistical Learning to Design New Materials

Advanced Intelligent Discovery, EarlyView.
Combining machine learning and probabilistic statistical learning is a powerful way to discover and design new materials. A variety of machine learning approaches can be used to identify promising candidates for target applications, and causal inference can help identify potential ways to make them a reality.
Jonathan Y. C. Ting, Amanda S. Barnard
wiley   +1 more source

Microenvironment Engineering Enables Broad Strategies for Lithium-Sulfur Batteries. [PDF]

Adv Sci (Weinh)
Li R, Xiao Y, Huang S.
europepmc   +1 more source

In situ unveiling the conversion processes on the catalytic cathode in lithium-sulfur batteries. [PDF]

Sci Adv
Li Y, Tian JX, Zhang XS, Liu RZ, Shen ZZ, Li HN, Lang SY, Wen R.   +7 more
europepmc   +1 more source