Silicon Asymmetric Membranes for Efficient Lithium Storage- A Highly Scalable Method

Ji Wu; Hao Chen; Clifford W. Padgett

doi:10.1002/ente.201500315

Silicon Asymmetric Membranes for Efficient Lithium Storage- A Highly Scalable Method

Ji Wu, Hao Chen, Clifford W. Padgett

Biochemistry, Chemistry & Physics

Georgia Southern University

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

In this study, scalable membrane technologies are adapted to obtain silicon asymmetric membranes for lithium-ion battery anodes. The unique asymmetric porous structure can provide both mechanical support and free volume to accommodate the large volume expansion during silicon lithiation, thus leading to excellent rate and cycling performance. An overall specific capacity as high as 1500mAhg^-1 was achieved at 100mAg^-1. Even at 1000mAg^-1, the capacity was still above 800mAhg^-1. More than 90% of the initial capacity was retained after 200cycles. It was also observed that a lower Si content and higher carbonization temperature can help achieve stable cycling performance in general. This report is significant in terms of demonstrating a simplistic, generic, and scalable method to create a robust, porous asymmetric membrane structure for efficient lithium-ion storage.

Original language	American English
Journal	Energy Technology
Volume	4
DOIs	https://doi.org/10.1002/ente.201500315
State	Published - Apr 1 2016

Disciplines

Chemistry

Keywords

Asymmetric membrane
Lithium-ion batteries
Phase inversion
Porous materials
Silicon

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/ente.201500315License: Unspecified

http://dx.doi.org/10.1002/ente.201500315

Cite this

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title = "Silicon Asymmetric Membranes for Efficient Lithium Storage- A Highly Scalable Method",

abstract = "In this study, scalable membrane technologies are adapted to obtain silicon asymmetric membranes for lithium-ion battery anodes. The unique asymmetric porous structure can provide both mechanical support and free volume to accommodate the large volume expansion during silicon lithiation, thus leading to excellent rate and cycling performance. An overall specific capacity as high as 1500mAhg-1 was achieved at 100mAg-1. Even at 1000mAg-1, the capacity was still above 800mAhg-1. More than 90% of the initial capacity was retained after 200cycles. It was also observed that a lower Si content and higher carbonization temperature can help achieve stable cycling performance in general. This report is significant in terms of demonstrating a simplistic, generic, and scalable method to create a robust, porous asymmetric membrane structure for efficient lithium-ion storage.",

keywords = "Asymmetric membrane, Lithium-ion batteries, Phase inversion, Porous materials, Silicon",

author = "Ji Wu and Hao Chen and Padgett, {Clifford W.}",

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year = "2016",

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doi = "10.1002/ente.201500315",

language = "American English",

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T1 - Silicon Asymmetric Membranes for Efficient Lithium Storage- A Highly Scalable Method

AU - Wu, Ji

AU - Chen, Hao

AU - Padgett, Clifford W.

PY - 2016/4/1

Y1 - 2016/4/1

N2 - In this study, scalable membrane technologies are adapted to obtain silicon asymmetric membranes for lithium-ion battery anodes. The unique asymmetric porous structure can provide both mechanical support and free volume to accommodate the large volume expansion during silicon lithiation, thus leading to excellent rate and cycling performance. An overall specific capacity as high as 1500mAhg-1 was achieved at 100mAg-1. Even at 1000mAg-1, the capacity was still above 800mAhg-1. More than 90% of the initial capacity was retained after 200cycles. It was also observed that a lower Si content and higher carbonization temperature can help achieve stable cycling performance in general. This report is significant in terms of demonstrating a simplistic, generic, and scalable method to create a robust, porous asymmetric membrane structure for efficient lithium-ion storage.

AB - In this study, scalable membrane technologies are adapted to obtain silicon asymmetric membranes for lithium-ion battery anodes. The unique asymmetric porous structure can provide both mechanical support and free volume to accommodate the large volume expansion during silicon lithiation, thus leading to excellent rate and cycling performance. An overall specific capacity as high as 1500mAhg-1 was achieved at 100mAg-1. Even at 1000mAg-1, the capacity was still above 800mAhg-1. More than 90% of the initial capacity was retained after 200cycles. It was also observed that a lower Si content and higher carbonization temperature can help achieve stable cycling performance in general. This report is significant in terms of demonstrating a simplistic, generic, and scalable method to create a robust, porous asymmetric membrane structure for efficient lithium-ion storage.

KW - Asymmetric membrane

KW - Lithium-ion batteries

KW - Phase inversion

KW - Porous materials

KW - Silicon

UR - https://digitalcommons.georgiasouthern.edu/chem-facpubs/79

UR - http://dx.doi.org/10.1002/ente.201500315

U2 - 10.1002/ente.201500315

DO - 10.1002/ente.201500315

M3 - Article

SN - 2194-4288

VL - 4

JO - Energy Technology

JF - Energy Technology

ER -

Silicon Asymmetric Membranes for Efficient Lithium Storage- A Highly Scalable Method

Abstract

Disciplines

Keywords

UN SDGs

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