| Literature DB >> 30393707 |
Xingxing Gu1, Lingbao Xin2, Yang Li3, Fan Dong4, Min Fu4, Yanglong Hou5.
Abstract
The desire for practical utilization of rechargeable lithium batteries with high energy density has motivated attempts to develop new electrode materials and battery systems. Here, without additional binders we preEntities:
Keywords: Free-standing; Graphene; Li–Se batteries; N,S-codoped; Ultra-lightweight; Vacuum filtration
Year: 2018 PMID: 30393707 PMCID: PMC6199105 DOI: 10.1007/s40820-018-0213-5
Source DB: PubMed Journal: Nanomicro Lett ISSN: 2150-5551
Fig. 1N,S-G membrane as an interlayer for trapping polyselenides
Fig. 2a XRD patterns of GO and N,S-G. b Raman spectra of GO and N,S-G
Fig. 3a XPS spectrum of N,S-G and high-resolution b C 1s, c N 1s, and d S 2p spectra
Fig. 4TEM images of a GO and b N,S-G. SEM images of N,S-G membrane in: c top view, d side view, and e the free-standing N,S-G membrane
Fig. 5CV curves of the first three cycles for Li–Se batteries a with and b without N,S-G interlayer at a scan rate of 0.1 mV s−1. Galvanostatic charge/discharge voltage profiles of Li–Se batteries c with and d without N,S-G interlayer at 1 C between 1.5 and 3.0 V
Fig. 6a Rate performance of Li–Se cells with and without N,S-G interlayer. b Long-term cycling performance of Li–Se cells with and without N,S-G interlayer
Fig. 7a Digital photographs of polyselenide adsorption by N,S-G interlayers. High-resolution b Se 3d and c S 2p XPS spectra of N,S-G interlayer after 500 discharge cycles
Fig. 8Z as a function of ω−1/2 in the low-frequency region