Research progress on bipolar membrane electrodialysis for resource and environmental applications

WANG Quanfu; JIANG Weiwei; XU Ying; WANG Xiaolong; FU Caixia; ZHU Jing; ZHUANG Haoyun; ZHU Zongqiang; ZHANG Gong

doi:10.13205/j.hjgc.202603005

Volume 44 Issue 3

Mar. 2026

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Article Navigation > ENVIRONMENTAL ENGINEERING > 2026 > 44(3): 58-72

WANG Quanfu, JIANG Weiwei, XU Ying, WANG Xiaolong, FU Caixia, ZHU Jing, ZHUANG Haoyun, ZHU Zongqiang, ZHANG Gong. Research progress on bipolar membrane electrodialysis for resource and environmental applications[J]. ENVIRONMENTAL ENGINEERING , 2026, 44(3): 58-72. doi: 10.13205/j.hjgc.202603005

Citation:

WANG Quanfu, JIANG Weiwei, XU Ying, WANG Xiaolong, FU Caixia, ZHU Jing, ZHUANG Haoyun, ZHU Zongqiang, ZHANG Gong. Research progress on bipolar membrane electrodialysis for resource and environmental applications[J]. ENVIRONMENTAL ENGINEERING , 2026, 44(3): 58-72. doi: 10.13205/j.hjgc.202603005

Citation:

WANG Quanfu, JIANG Weiwei, XU Ying, WANG Xiaolong, FU Caixia, ZHU Jing, ZHUANG Haoyun, ZHU Zongqiang, ZHANG Gong. Research progress on bipolar membrane electrodialysis for resource and environmental applications[J]. ENVIRONMENTAL ENGINEERING , 2026, 44(3): 58-72. doi: 10.13205/j.hjgc.202603005

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Research progress on bipolar membrane electrodialysis for resource and environmental applications

doi: 10.13205/j.hjgc.202603005

1. Guangxi Key Laboratory of Environmental Pollution Control Theory and Technology，Guilin University of Technology，Guilin 541006，China;
2. Center of Technology Innovation，Wuxi City Environmental Technology Co.，Ltd.，Wuxi 214026，China;
3. Wuxi Public Utilities Environment Testing Research Institute Co.，Ltd.，Wuxi 214063，China;
4. NanFang Smart Water Technology Co.，Ltd.，Hangzhou 310000，China;
5. Wuxi Industrial Waste Safety Disposal Co.，Ltd.，Wuxi 214000，China;
6. Center for Water and Ecology，School of Environment，Tsinghua University，Beijing 100084，China

Received Date: 2025-11-28
Available Online: 2026-04-11
Publish Date: 2026-03-01

Abstract

Abstract

Against the backdrop of increasingly severe global sustainability challenges， Bipolar Membrane Electrodialysis （BMED） technology is emerging as a pivotal solution driving transformation in the chemical， environmental， and resource management sectors. This technology not only demonstrates remarkable efficiency and economic benefits in critical areas such as resource extraction， pollution control， and CO₂ capture but also exhibits substantial potential for large-scale commercial implementation. This review systematically outlines the working principles and fabrication methods of bipolar membranes， along with their applications across various industrial fields， highlighting their significant capacity to advance greener and more efficient industrial processes. Representative case studies in resource recovery， pollution mitigation， and CO₂ capture are presented to illustrate the promising industrial prospects of BMED and validate its practical value in enabling sustainable resource utilization and environmental protection.
- bipolar membrane,
- resource extraction,
- pollution control,
- acid and base recovery,
- CO₂ capture

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References(101)

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