News Release

Mussel-inspired membrane can boost sustainability and add value to industrial wastewater treatment

New nanoporous membrane allows highly efficient separation of wastewater components for future reuse, offering industries sustainability and added-value benefits

Peer-Reviewed Publication

University of Bath

Mussel-inspired membrane

image: Researchers have developed a new highly-efficient membrane inspired by mussels view more 

Credit: University of Bath

Engineers have developed a new kind of membrane that separates chemicals within wastewater so effectively that they can be reused, presenting a new opportunity for industries to improve sustainability, while extracting valuable by-products and chemicals from wastewater.

Created for use in wastewater treatment, the thin-film composite nanoporous membrane known as a TFC NPM, exhibits an ‘unprecedented’ capability to separate salts and other chemical components from water, and could lead to more sustainable treatment and management of water in a range of industries.

A research paper published today in Nature Water details the membrane’s performance and explains how its unique properties, aspects of which are inspired by mussels, could pave the way for more sustainable management of water within industries such as pharmaceuticals, oil and gas, textiles and food processing. The paper is authored by academics from the UK’s University of Bath alongside colleagues based in China, South Korea, Singapore, Australia and Belgium.

They say the membrane could replace current equivalents used in electrodialysis, a process used to treat water by transporting ions through membranes from one solution to another under an electrical current. Existing membranes are expensive and can achieve separation efficiencies of 90-95%. The authors of the new work say the new TFC NPM can improve on this significantly, with efficiencies of more than 99%, while using less energy at a lower cost.

Dr Ming Xie, lecturer in Chemical Engineering at the University of Bath and one of the paper’s authors, says the membrane could lead to a shift in thinking around wastewater treatment. He says: “Traditionally, many industries have regarded the wastewater they create as a trade waste that is a necessary cost of business. Technologies such as the membrane we have created can help us take steps toward lowering carbon emissions by reducing the energy requirement of wastewater treatment, while finding ways to efficiently separate the components in it such as chemicals, salts, energy, biomass and nutrients, before reusing them as high-value by-products.”

The researchers took inspiration from mussels when designing the coating on the membrane surface, which is made up of the polymer polyethyleneimine (PEI) and polydopamine (PDA), a compound which mussels excrete and use to stick to rocks or wood in wet conditions. The coating’s stickiness makes the membrane highly selective, allowing water to pass through but blocking other compounds and organic materials. This multi-stage process results in improved filtration of the water, and a highly efficient, low-energy way to fractionate (or separate) chemicals individually.

Electrodialysis is a technology that has shown its adaptability to several applications, in this case, management of highly saline waste streams. In the electrodialysis process, electrical potential is used to drive the positive and negative ions of dissolved salts through separate semipermeable synthetic membrane.

During tests, the researchers used four antibiotics – ceftriaxone sodium, cefotaxime sodium, carbenicillin disodium and ampicillin sodium – to prove the PDA/PEI-coated membrane’s electro-driven filtration performance. The membrane showed unprecedentedly high recovery efficiency in removing the antibiotics from saltwater solutions (water and NaCl sodium chloride) – with more than 99.3% desalination efficiency and more than 99.1% recovery of the antibiotics. If incorporated in industrial wastewater treatment, the membrane has the capability to carry out highly effective electrodialytic fractionation (separation) of various organic/NaCl mixed solutions, more effectively than standard existing processes.

Co-author, Dr Dong Han Seo from Department of Energy Engineering, Korea Institute of Energy Technology, said “This work demonstrates the state of the art electrodialysis to address the grand challenge in the pharmaceutical industry to bio based wastewater treatment, to enable effective recovery of the high value chemicals while obtaining reusable water in the other end using a low energy consumption.”

Dr Jiuyang Lin from the Chinese Academy of Sciences, also a co-author, said: “This simple yet effective coating provides long term stability and guarantees low energy consumption regardless of the wastewater conditions. This is a breakthrough finding electrodialysis for wastewater treatment involving clever design of membrane, simulation and analysis.”

The research paper, Shielding effect enables fast ion transfer through nanoporous membrane for highly energy-efficient electrodialysis, is published in Nature Water today (3 August 2023). You can read the paper at (DOI: 10.1038/s44221-023-00113-5).

The authors are exploring routes to commercialise the membrane and would welcome approaches from relevant parties.

The project was supported by funding from a Royal Society International Exchange grant, a Royal Academy of Engineering Industrial Fellowship and the Erasmus Staff Mobility Fund.

Academics at the University of Bath have recently set up the Engineering Porous Materials at Multiple Scales (EPoMM) network to explore other ways to encourage cross-discipline innovation in the field of porous materials.



For more information or to request interviews, contact Will McManus at or on +44(0) 1225 385 798.

The authors of the paper (affiliations in brackets) are:

Ming Xie (Department of Chemical Engineering, University of Bath, Bath, UK)

Wenyuan Ye (Fujian Provincial Key Laboratory of Soil Environmental Health and Regulation, College of Resources and Environment, Fujian Agriculture and Forestry University, Fuzhou, China)

Shuangling Xie, Jiale Du, Riri Liu, Xiangyu Chen, Zijian Yu, Shengqiong Fang (College of Environment and Safety Engineering, Fuzhou University, Fuzhou, China)

Dong Zou, Young Moo Lee (Department of Energy Engineering, College of Engineering, Hanyang University, Seoul, Republic of Korea)

Elisa Yun Mei Ang (Engineering Cluster, Singapore Institute of Technology, Singapore)

William Toh, Teng Yong Ng (School of Mechanical and Aerospace Engineering, Nanyang Technological University, Singapore)

Dan Dan Han (College of Mechanical and Vehicle Engineering, Hunan University, Changsha, China)

Dong Han Seo (Institute of Energy Materials and Devices, Korea Institute of Energy Technology  (KENTECH), Naju, Republic of Korea)

Shuaifei Zhao (Institute for Frontier Materials, Deakin University, Geelong, Victoria, Australia)

Bart Van der Bruggen (Process Engineering for Sustainable Systems (ProcESS), Department of Chemical Engineering, KU Leuven, Leuven, Belgium)

Jiuyang Lin (Ganjiang Innovation Academy, Chinese Academy of Sciences, Ganzhou, China; Jiangxi Province Key Laboratory of Cleaner Production of Rare Earths, Ganzhou, China; Key Laboratory of Rare Earths, Chinese Academy of Sciences, Ganzhou, China; College of Environment and Safety Engineering, Fuzhou University, Fuzhou, China)

The University of Bath 

The University of Bath is one of the UK's leading universities for high-impact research with a reputation for excellence in education, student experience and graduate prospects. 

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