Plasma-functionalized carbon-layered separators for improved performance of lithium sulfur batteries

Title
Plasma-functionalized carbon-layered separators for improved performance of lithium sulfur batteries
Authors
하흥용안지훈신현진살림 아바스이관영
Keywords
functional separators; ion conductivity; lithium sulfur battery; plasma treatment
Issue Date
2019-02
Publisher
Journal of materials chemistry. A, Materials for energy and sustainability
Citation
VOL 7, NO 8-3782
Abstract
Lithium– sulfur (Li– S) batteries are one of the most promising next generation secondary batteries due to high energy capacity and low cost. However, they suffer from the loss of active material, insulating nature of sulfur, degradation of the lithium anode and fast capacity fading due to polysulfide shuttling. In this work, a novel approach has been made to improve the performance of the Li– S battery by using functional separators that are modified using a plasma technique. The plasma-modified functional separator is made by firstly irradiating a polymer separator with a plasma, secondly followed by coating it with a thin carbon layer which is then thirdly subjected to an additional plasma treatment to modify the carbon layer. The plasma treatment generates various functional groups on the surfaces of the polymer separator and the carbon layer. The plasma-modified functional separator is found to provide more wettability, electric conduction paths and active sites that could facilitate the redox reactions and lithium ion transport as well as reduce the polysulfide shuttling, ultimately leading to a dramatic improvement in the performance of the Li– S battery. Among various plasma gases tested, such as CO2, N2 and O2, the CO2 plasma is found to be the most effective in improving the electrochemical properties of the functional separators. The polysulfide permeation rate through the CO2-plasma-modified functional separator is reduced by about 70 times and the Li– S battery employing the functional separator displays an initial capacity of 1204 mA h g− 1 and a remaining capacity of 802 mA h g− 1 after 100 cycles at 0.2C rate, which account for 57% and 61% increments, respectively, as compared with those of the cell using a pristine separator. In-depth physicochemical and electrochemical analyses have also been carried out to characterize the modified separators and carbon layers and
URI
http://pubs.kist.re.kr/handle/201004/69016
ISSN
2050-7488
Appears in Collections:
KIST Publication > Article
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