Ceramics International, volume 48, issue 18, pages 25949-25957

Boosting lithium-ion transport capability of LAGP/PPO composite solid electrolyte via component regulation from ‘Ceramics-in-Polymer’ to ‘Polymer-in-Ceramics'

Zhenhao Huang ¹

Jie Li ¹

Lin-xin Li ¹

Huimin Xu ¹

Changseok Han ¹

Ming-Quan Liu ²

Jun Xiang ³

Xiangqian Shen ¹

Mao-xiang Jing ¹

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Institute for Advanced Materials, School of Materials Science and Engineering, Jiangsu University, Zhenjiang, 212013, China |

School of Mechanical Engineering, Jiangsu University, Zhenjiang, 212013, China |

School of Science, Jiangsu University of Science and Technology, Zhenjiang, 212100, China |

Publication type: Journal Article

Publication date: 2022-09-01

Elsevier

Journal: Ceramics International

Quartile SCImago

Quartile WOS

Impact factor: 5.2

ISSN: 02728842

DOI: 10.1016/j.ceramint.2022.05.274

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Materials Chemistry

Surfaces, Coatings and Films

Ceramics and Composites

Electronic, Optical and Magnetic Materials

Process Chemistry and Technology

Abstract

The design and regulation of the ion transport channels in the polymer electrolyte is an important means to improve the lithium ion transport behavior of the electrolyte. In this work, we for the first time combined the high ionic conductive inorganic ceramic electrolyte Li 1.5 Al 0.5 Ge 1.5 (PO 4 ) 3 (LAGP) with flexible polypropylene oxide (PPO) polymer electrolyte to synthesize a high-filling LAGP/PPO composite solid electrolyte film and regulated the ion transport channels from ‘Ceramics-in-Polymer’ mode to ‘Polymer-in-Ceramics' mode by optimizing the ratio of LAGP vs. PPO. The results reveal that when the LAGP content <40%, the electrolyte belongs to ‘LAGP-in-PPO’, and then changes to ‘PPO-in-LAGP’ when the LAGP content exceeds 40%. Compared with ‘LAGP-in-PPO’, the ‘PPO-in-LAGP’ shows better comprehensive properties, especially for the 75% LAGP-filled PPO electrolyte, the room-temperature ionic conductivity is as high as 3.46 × 10 −4 Scm −1 , the ion migration number and voltage stable window reach 0.83 and 4.78 V respectively. This high-filled composite electrolyte possesses high tensile stress of 40 MPa with a strain of 46% and withstands working environment up to 200 °C. The NCM622/Li solid-state battery composed of this electrolyte also presents good rate and cycle performances with a capacity retention of 80% after 230 cycles at 0.3C because of its high ion transport capability and good inhibition of lithium dendrites. This composite structural design is expected to develop high-performance solid-state electrolytes suitable for high-voltage solid-state lithium batteries.

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Citations by journals

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Colloids and Surfaces A: Physicochemical and Engineering Aspects	Colloids and Surfaces A: Physicochemical and Engineering Aspects, 4, 18.18% Colloids and Surfaces A: Physicochemical and Engineering Aspects 4 publications, 18.18%
Nano-Micro Letters	Nano-Micro Letters, 1, 4.55% Nano-Micro Letters 1 publication, 4.55%
Journal of Rare Earths	Journal of Rare Earths, 1, 4.55% Journal of Rare Earths 1 publication, 4.55%
Ceramics International	Ceramics International, 1, 4.55% Ceramics International 1 publication, 4.55%
Materials Chemistry Frontiers	Materials Chemistry Frontiers, 1, 4.55% Materials Chemistry Frontiers 1 publication, 4.55%
Batteries & Supercaps	Batteries & Supercaps, 1, 4.55% Batteries & Supercaps 1 publication, 4.55%
Renewable and Sustainable Energy Reviews	Renewable and Sustainable Energy Reviews, 1, 4.55% Renewable and Sustainable Energy Reviews 1 publication, 4.55%
Journal of the Electrochemical Society	Journal of the Electrochemical Society, 1, 4.55% Journal of the Electrochemical Society 1 publication, 4.55%
Solid State Ionics	Solid State Ionics, 1, 4.55% Solid State Ionics 1 publication, 4.55%
Nanotechnology	Nanotechnology, 1, 4.55% Nanotechnology 1 publication, 4.55%
Journal of the American Chemical Society	Journal of the American Chemical Society, 1, 4.55% Journal of the American Chemical Society 1 publication, 4.55%
Polymer Testing	Polymer Testing, 1, 4.55% Polymer Testing 1 publication, 4.55%
ACS Applied Energy Materials	ACS Applied Energy Materials, 1, 4.55% ACS Applied Energy Materials 1 publication, 4.55%
Journal of Power Sources	Journal of Power Sources, 1, 4.55% Journal of Power Sources 1 publication, 4.55%
Russian Chemical Reviews	Russian Chemical Reviews, 1, 4.55% Russian Chemical Reviews 1 publication, 4.55%
Next Materials	Next Materials, 1, 4.55% Next Materials 1 publication, 4.55%
Advanced Energy Materials	Advanced Energy Materials, 1, 4.55% Advanced Energy Materials 1 publication, 4.55%
Applied Physics A: Materials Science and Processing	Applied Physics A: Materials Science and Processing, 1, 4.55% Applied Physics A: Materials Science and Processing 1 publication, 4.55%
Applied Materials Today	Applied Materials Today, 1, 4.55% Applied Materials Today 1 publication, 4.55%
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Citations by publishers

	2 4 6 8 10 12
Elsevier	Elsevier, 12, 54.55% Elsevier 12 publications, 54.55%
Springer Nature	Springer Nature, 2, 9.09% Springer Nature 2 publications, 9.09%
Wiley	Wiley, 2, 9.09% Wiley 2 publications, 9.09%
American Chemical Society (ACS)	American Chemical Society (ACS), 2, 9.09% American Chemical Society (ACS) 2 publications, 9.09%
Royal Society of Chemistry (RSC)	Royal Society of Chemistry (RSC), 1, 4.55% Royal Society of Chemistry (RSC) 1 publication, 4.55%
The Electrochemical Society	The Electrochemical Society, 1, 4.55% The Electrochemical Society 1 publication, 4.55%
IOP Publishing	IOP Publishing, 1, 4.55% IOP Publishing 1 publication, 4.55%
Autonomous Non-profit Organization Editorial Board of the journal Uspekhi Khimii	Autonomous Non-profit Organization Editorial Board of the journal Uspekhi Khimii, 1, 4.55% Autonomous Non-profit Organization Editorial Board of the journal Uspekhi Khimii 1 publication, 4.55%
	2 4 6 8 10 12

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Huang Z. et al. Boosting lithium-ion transport capability of LAGP/PPO composite solid electrolyte via component regulation from ‘Ceramics-in-Polymer’ to ‘Polymer-in-Ceramics' // Ceramics International. 2022. Vol. 48. No. 18. pp. 25949-25957.

GOST all authors (up to 50) Copy

Huang Z., Li J., Li L., Xu H., Han C., Liu M., Xiang J., Shen X., Jing M. Boosting lithium-ion transport capability of LAGP/PPO composite solid electrolyte via component regulation from ‘Ceramics-in-Polymer’ to ‘Polymer-in-Ceramics' // Ceramics International. 2022. Vol. 48. No. 18. pp. 25949-25957.

RIS |

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RIS Copy

TY - JOUR

DO - 10.1016/j.ceramint.2022.05.274

UR - https://doi.org/10.1016/j.ceramint.2022.05.274

TI - Boosting lithium-ion transport capability of LAGP/PPO composite solid electrolyte via component regulation from ‘Ceramics-in-Polymer’ to ‘Polymer-in-Ceramics'

T2 - Ceramics International

AU - Huang, Zhenhao

AU - Li, Jie

AU - Li, Lin-xin

AU - Xu, Huimin

AU - Han, Changseok

AU - Liu, Ming-Quan

AU - Xiang, Jun

AU - Shen, Xiangqian

AU - Jing, Mao-xiang

PY - 2022

DA - 2022/09/01 00:00:00

PB - Elsevier

SP - 25949-25957

IS - 18

VL - 48

SN - 0272-8842

ER -

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@article{2022_Huang,

author = {Zhenhao Huang and Jie Li and Lin-xin Li and Huimin Xu and Changseok Han and Ming-Quan Liu and Jun Xiang and Xiangqian Shen and Mao-xiang Jing},

title = {Boosting lithium-ion transport capability of LAGP/PPO composite solid electrolyte via component regulation from ‘Ceramics-in-Polymer’ to ‘Polymer-in-Ceramics'},

journal = {Ceramics International},

year = {2022},

volume = {48},

publisher = {Elsevier},

month = {sep},

url = {https://doi.org/10.1016/j.ceramint.2022.05.274},

number = {18},

pages = {25949--25957},

doi = {10.1016/j.ceramint.2022.05.274}

}

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MLA Copy

Huang, Zhenhao, et al. “Boosting lithium-ion transport capability of LAGP/PPO composite solid electrolyte via component regulation from ‘Ceramics-in-Polymer’ to ‘Polymer-in-Ceramics'.” Ceramics International, vol. 48, no. 18, Sep. 2022, pp. 25949-25957. https://doi.org/10.1016/j.ceramint.2022.05.274.

Found error?

Publisher

Elsevier

Journal

Ceramics International

Quartile SCImago

Quartile WOS

Impact factor

5.2

ISSN

02728842 (Print)

Profiles

Han, Changseok