Porous Organic Polymer with Hierarchical Structure and Limited Volume Expansion for Ultrafast and Highly Durable Sodium Storage

Longhai Zhang; Rui Wang; Zixiang Liu; Jiandong Wan; Shilin Zhang; Siming Wang; Kang Hua; Xiaohao Liu; Xunzhu Zhou; Xiansheng Luo; Xiaoyang Zhang; Mengge Cao; Hongwei Kang; Chaofeng Zhang; Zaiping Guo

doi:10.1002/adma.202210082

Porous Organic Polymer with Hierarchical Structure and Limited Volume Expansion for Ultrafast and Highly Durable Sodium Storage

Longhai Zhang
, Rui Wang
, Zixiang Liu
, Jiandong Wan
, Shilin Zhang
, Siming Wang
, Kang Hua
, Xiaohao Liu
, Xunzhu Zhou
, Xiansheng Luo
, Xiaoyang Zhang
, Mengge Cao
, Hongwei Kang^*
, Chaofeng Zhang^*
, Zaiping Guo

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

124 Citations (Scopus)

Abstract

Sustainable organic electrode materials, as promising alternatives to conventional inorganic electrode materials for sodium-ion batteries (SIBs), are still challenging to realize long-lifetime and high-rate batteries because of their poor conductivity, limited electroactivity, and severe dissolution. It is also urgent to deeply reveal their electrochemical mechanism and evolution processes. A porous organic polymer (POP) with a conjugated and hierarchical structure is designed and synthesized here. The unique molecule and structure endow the POP with electron delocalization, high ionic diffusivity, plentiful active sites, exceptional structure stability, and limited solubility in electrolytes. When evaluated as an anode for SIBs, the POP exhibits appealing electrochemical properties regarding reversible capacity, rate behaviors, and long-duration life. Importantly, using judiciously combined experiments and theoretical computation, including in situ transmission electron microscopy (TEM), and ex situ spectroscopy, we reveal the Na-storage mechanism and dynamic evolution processes of the POP, including 12-electron reaction process with Na, low volume expansion (125–106% vs the initial 100%), and stable composition and structure evolution during repeating sodiation/de-sodiation processes. This quantitative design for ultrafast and highly durable sodium storage in the POP could be of immediate benefit for the rational design of organic electrode materials with ideal electrochemical properties. © 2023 Wiley-VCH GmbH.

Original language	English
Article number	2210082
Journal	Advanced Materials
Volume	35
Issue number	17
Online published	4 Feb 2023
DOIs	https://doi.org/10.1002/adma.202210082
Publication status	Published - 26 Apr 2023
Externally published	Yes

Funding

L.Z. and R.W. contributed equally to this work. The authors thank the financial support from the National Natural Science Foundation of China (52172173 and 51872071), Natural Science Foundation of Anhui Province for Distinguished Young Scholar (2108085J25), Excellent Research and Innovation Team Project of Anhui Province (2022AH010001), Anhui Province Key Laboratory of Environment-Friendly Polymer Materials, Natural Science Foundation of Anhui Province (2208085QE130), and Natural Science Research Projects of Universities in Anhui Province (KJ2020A0021, KJ2020A0547). The High-performance Computing Platform of Anhui University provides computing resources. The authors also acknowledge Dr. Weiqiang Tang and Prof. Qiquan Luo for conducting theoretical calculations. H.W.K. acknowledges the Talent program of Fuyang Normal University (2020KYQD0015). This work was also supported by the Open Fund of Guangdong Provincial Key Laboratory of Advance Energy Storage Materials (AESM202106).

UN SDGs

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

SDG 7 Affordable and Clean Energy

Research Keywords

electrode materials
low volume expansion
polymerization strategies
porous organic polymers
sodium-ion batteries

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title = "Porous Organic Polymer with Hierarchical Structure and Limited Volume Expansion for Ultrafast and Highly Durable Sodium Storage",

abstract = "Sustainable organic electrode materials, as promising alternatives to conventional inorganic electrode materials for sodium-ion batteries (SIBs), are still challenging to realize long-lifetime and high-rate batteries because of their poor conductivity, limited electroactivity, and severe dissolution. It is also urgent to deeply reveal their electrochemical mechanism and evolution processes. A porous organic polymer (POP) with a conjugated and hierarchical structure is designed and synthesized here. The unique molecule and structure endow the POP with electron delocalization, high ionic diffusivity, plentiful active sites, exceptional structure stability, and limited solubility in electrolytes. When evaluated as an anode for SIBs, the POP exhibits appealing electrochemical properties regarding reversible capacity, rate behaviors, and long-duration life. Importantly, using judiciously combined experiments and theoretical computation, including in situ transmission electron microscopy (TEM), and ex situ spectroscopy, we reveal the Na-storage mechanism and dynamic evolution processes of the POP, including 12-electron reaction process with Na, low volume expansion (125–106\% vs the initial 100\%), and stable composition and structure evolution during repeating sodiation/de-sodiation processes. This quantitative design for ultrafast and highly durable sodium storage in the POP could be of immediate benefit for the rational design of organic electrode materials with ideal electrochemical properties. {\textcopyright} 2023 Wiley-VCH GmbH.",

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author = "Longhai Zhang and Rui Wang and Zixiang Liu and Jiandong Wan and Shilin Zhang and Siming Wang and Kang Hua and Xiaohao Liu and Xunzhu Zhou and Xiansheng Luo and Xiaoyang Zhang and Mengge Cao and Hongwei Kang and Chaofeng Zhang and Zaiping Guo",

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T1 - Porous Organic Polymer with Hierarchical Structure and Limited Volume Expansion for Ultrafast and Highly Durable Sodium Storage

AU - Zhang, Longhai

AU - Wang, Rui

AU - Liu, Zixiang

AU - Wan, Jiandong

AU - Zhang, Shilin

AU - Wang, Siming

AU - Hua, Kang

AU - Liu, Xiaohao

AU - Zhou, Xunzhu

AU - Luo, Xiansheng

AU - Zhang, Xiaoyang

AU - Cao, Mengge

AU - Kang, Hongwei

AU - Zhang, Chaofeng

AU - Guo, Zaiping

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N2 - Sustainable organic electrode materials, as promising alternatives to conventional inorganic electrode materials for sodium-ion batteries (SIBs), are still challenging to realize long-lifetime and high-rate batteries because of their poor conductivity, limited electroactivity, and severe dissolution. It is also urgent to deeply reveal their electrochemical mechanism and evolution processes. A porous organic polymer (POP) with a conjugated and hierarchical structure is designed and synthesized here. The unique molecule and structure endow the POP with electron delocalization, high ionic diffusivity, plentiful active sites, exceptional structure stability, and limited solubility in electrolytes. When evaluated as an anode for SIBs, the POP exhibits appealing electrochemical properties regarding reversible capacity, rate behaviors, and long-duration life. Importantly, using judiciously combined experiments and theoretical computation, including in situ transmission electron microscopy (TEM), and ex situ spectroscopy, we reveal the Na-storage mechanism and dynamic evolution processes of the POP, including 12-electron reaction process with Na, low volume expansion (125–106% vs the initial 100%), and stable composition and structure evolution during repeating sodiation/de-sodiation processes. This quantitative design for ultrafast and highly durable sodium storage in the POP could be of immediate benefit for the rational design of organic electrode materials with ideal electrochemical properties. © 2023 Wiley-VCH GmbH.

AB - Sustainable organic electrode materials, as promising alternatives to conventional inorganic electrode materials for sodium-ion batteries (SIBs), are still challenging to realize long-lifetime and high-rate batteries because of their poor conductivity, limited electroactivity, and severe dissolution. It is also urgent to deeply reveal their electrochemical mechanism and evolution processes. A porous organic polymer (POP) with a conjugated and hierarchical structure is designed and synthesized here. The unique molecule and structure endow the POP with electron delocalization, high ionic diffusivity, plentiful active sites, exceptional structure stability, and limited solubility in electrolytes. When evaluated as an anode for SIBs, the POP exhibits appealing electrochemical properties regarding reversible capacity, rate behaviors, and long-duration life. Importantly, using judiciously combined experiments and theoretical computation, including in situ transmission electron microscopy (TEM), and ex situ spectroscopy, we reveal the Na-storage mechanism and dynamic evolution processes of the POP, including 12-electron reaction process with Na, low volume expansion (125–106% vs the initial 100%), and stable composition and structure evolution during repeating sodiation/de-sodiation processes. This quantitative design for ultrafast and highly durable sodium storage in the POP could be of immediate benefit for the rational design of organic electrode materials with ideal electrochemical properties. © 2023 Wiley-VCH GmbH.

KW - electrode materials

KW - low volume expansion

KW - polymerization strategies

KW - porous organic polymers

KW - sodium-ion batteries

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M3 - RGC 21 - Publication in refereed journal

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Porous Organic Polymer with Hierarchical Structure and Limited Volume Expansion for Ultrafast and Highly Durable Sodium Storage

Abstract

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