SFX by Ex Libris Inc.

Title:	Electrochemical Interphases for High-Energy Storage Using Reactive Metal Anodes
Source:	Accounts of Chemical Research [0001-4842] Shuya Wei, Snehashis yr:2017

Basic

Full text

Full text available via American Chemical Society Journals

Year:

Volume:

Issue:

Start Page:

Document delivery

Request document via Library/Bibliothek

Users interested in this article also expressed an interest in the following:
description	1.	Zhang, P. "Two-dimensional materials for miniaturized energy storage devices: from individual devices to smart integrated systems." Chemical Society reviews. 47.19: 7426-7451.
description	2.	Chen, L. "Highly Fluorinated Interphases Enable High-Voltage Li-Metal Batteries." Chem 4.1: 174-185.
description	3.	Liu, S F. "Recent development in lithium metal anodes of liquid-state rechargeable batteries." Journal of alloys and compounds 730.Supplement C: 135-149.
description	4.	Hu, Z. "A graphene oxide and ionic liquid assisted anion-immobilized polymer electrolyte with high ionic conductivity for dendrite-free lithium metal batteries." Journal of power sources 477: 228754-.
description	5.	"Challenges and Recent Progress in the Development of Si Anodes for Lithium-Ion Battery." Advanced energy materials. 7.23: 1700715-.
description	6.	Su, C. "Cyclic carbonate for highly stable cycling of high voltage lithium metal batteries." Energy Storage Materials 17 (2019): 284-292.
description	7.	"A highly concentrated phosphate-based electrolyte for high-safety rechargeable lithium batteries." Chemical communications : Chem comm / 54.35: 4453-4456.
description	8.	Chen, S. "High-Voltage Lithium-Metal Batteries Enabled by Localized High-Concentration Electrolytes." Advanced materials 30.21: 1706102-.
description	9.	Zhao, Qian g. "Carbon Paper Interlayers: A Universal and Effective Approach for Highly Stable Li Metal Anodes." Nano Energy 43 (2017): 368-375.
description	10.	Michan, Alison L. "Fluoroethylene Carbonate and Vinylene Carbonate Reduction: Understanding Lithium-Ion Battery Electrolyte Additives and Solid Electrolyte Interphase Formation." Chemistry of materials 28.22 (2016): 8149-8159.
description	11.	Yang, C. "Protected Lithium-Metal Anodes in Batteries: From Liquid to Solid." Advanced materials 29.36.
description	12.	Abdi, H. "Human passive motions and a user-friendly energy harvesting system." Journal of intelligent material systems and structures 25.8 (2014): 923-936.
description	13.	Rocha, J G. "Energy harvesting from piezoelectric materials fully integrated in footwear." IEEE transactions on industrial electronics 57.3 (2010): 813-819.
description	14.	Homann, G. "Poly(Ethylene Oxide)-based Electrolyte for Solid-State-Lithium-Batteries with High Voltage Positive Electrodes: Evaluating the Role of Electrolyte Oxidation in Rapid Cell Failure." Scientific Reports 10.1 (2020): 1-4390.
description	15.	Banitaba, Seyedeh N. "Nanofibrous poly(ethylene oxide)‐based structures incorporated with multi‐walled carbon nanotube and graphene oxide as all‐solid‐state electrolytes for lithium ion batteries." Polymer International 68.10 (2019): 1787-1794.
description	16.	Lin, Liangdong g. "Lithium Phosphide/Lithium Chloride Coating on Lithium for Advanced Lithium Metal Anode." Journal of Materials Chemistry A: Materials for energy and sustainability 6.32 (2018): 15859-15867.
description	17.	Fu, S. "Boosting Sodium Storage in TiO2Nanotube Arrays through Surface Phosphorylation." Advanced materials 30.6 (2018): 1704337-.
description	18.	Cheng, X. "Toward Safe Lithium Metal Anode in Rechargeable Batteries: A Review." Chemical reviews 117.15 (2017): 10403-10473.
description	19.	Wang, Chengwei W. "Conformal, Nanoscale ZnO Surface Modification of Garnet-Based Solid-State Electrolyte for Lithium Metal Anodes." Nano letters 17.1 (2017): 565-571.
description	20.	Lu, W. "Porous membranes in secondary battery technologies." Chemical Society reviews 46.8 (2017): 2199-2236.