Skin-replaceable antifouling cellulose ceramic membranes from jute agro-waste for sustainable and efficient oily wastewater treatment

Baig, Nadeem; Ahmad, Tauqir; Sufyan, Ali; Asif, Muhammad Bilal; Alqudaihi, Kawthar; Alrwaily, Balqees; Ahmed, Md Sabbir; Maniruzzaman, Md; Hussain, Arshad; Shah, Syed Shaheen; Larsson, J. Andreas; Aziz, Md Abdul

Skin-replaceable antifouling cellulose ceramic membranes from jute agro-waste for sustainable and efficient oily wastewater treatment

Mark

Baig, Nadeem ; Ahmad, Tauqir ; Sufyan, Ali ^LU ; Asif, Muhammad Bilal ; Alqudaihi, Kawthar ; Alrwaily, Balqees ; Ahmed, Md Sabbir ; Maniruzzaman, Md ; Hussain, Arshad and Shah, Syed Shaheen , et al. (2026) In npj Clean Water 9(1).

Abstract: Oily wastewater presents a serious environmental challenge, demanding sustainable and regenerative membrane technologies. Here, we report a green and scalable method for fabricating skin-replaceable cellulose membranes (SRC-M) from jute agro-waste, using a NaOH/urea activation route and argon-pressurized deposition onto ceramic supports. The resulting Cellulose II-based asymmetric membranes exhibit high water flux (~470 L m⁻²h⁻¹) and >98% oil rejection across various emulsions. Notably, the membrane’s surface can be fully renewed via ultrasonication, restoring >99% of the original flux after 16 fouling cycles. Density functional theory (DFT) calculations confirm the thermodynamic stability (ΔG = -0.162 eV) and low kinetic barrier... (More); Oily wastewater presents a serious environmental challenge, demanding sustainable and regenerative membrane technologies. Here, we report a green and scalable method for fabricating skin-replaceable cellulose membranes (SRC-M) from jute agro-waste, using a NaOH/urea activation route and argon-pressurized deposition onto ceramic supports. The resulting Cellulose II-based asymmetric membranes exhibit high water flux (~470 L m⁻²h⁻¹) and >98% oil rejection across various emulsions. Notably, the membrane’s surface can be fully renewed via ultrasonication, restoring >99% of the original flux after 16 fouling cycles. Density functional theory (DFT) calculations confirm the thermodynamic stability (ΔG = -0.162 eV) and low kinetic barrier (0.46 eV) of urea adsorption on cellulose, supporting the dissolution mechanism and regeneration behavior. This biodegradable, self-renewable membrane system offers a robust, circular solution for long-term oily wastewater remediation and aligns with green chemistry principles. (Figure presented.).
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/ab8c7ab3-8ac1-4729-85fa-45b9200c86d0

author

Baig, Nadeem ; Ahmad, Tauqir ; Sufyan, Ali ^LU ; Asif, Muhammad Bilal ; Alqudaihi, Kawthar ; Alrwaily, Balqees ; Ahmed, Md Sabbir ; Maniruzzaman, Md ; Hussain, Arshad and Shah, Syed Shaheen , et al. (More)

Baig, Nadeem ; Ahmad, Tauqir ; Sufyan, Ali ^LU ; Asif, Muhammad Bilal ; Alqudaihi, Kawthar ; Alrwaily, Balqees ; Ahmed, Md Sabbir ; Maniruzzaman, Md ; Hussain, Arshad ; Shah, Syed Shaheen ; Larsson, J. Andreas and Aziz, Md Abdul (Less)

organization

publishing date

2026

type

Contribution to journal

publication status

published

subject

in

npj Clean Water

volume

9

issue

1

article number

8

publisher

Springer Nature

external identifiers

scopus:105027879366

ISSN

2059-7037

DOI

10.1038/s41545-025-00538-3

language

English

LU publication?

yes

id

ab8c7ab3-8ac1-4729-85fa-45b9200c86d0

date added to LUP

2026-02-17 15:15:40

date last changed

2026-02-17 15:15:46

@article{ab8c7ab3-8ac1-4729-85fa-45b9200c86d0,
  abstract     = {{<p>Oily wastewater presents a serious environmental challenge, demanding sustainable and regenerative membrane technologies. Here, we report a green and scalable method for fabricating skin-replaceable cellulose membranes (SRC-M) from jute agro-waste, using a NaOH/urea activation route and argon-pressurized deposition onto ceramic supports. The resulting Cellulose II-based asymmetric membranes exhibit high water flux (~470 L m⁻²h⁻¹) and &gt;98% oil rejection across various emulsions. Notably, the membrane’s surface can be fully renewed via ultrasonication, restoring &gt;99% of the original flux after 16 fouling cycles. Density functional theory (DFT) calculations confirm the thermodynamic stability (ΔG = -0.162 eV) and low kinetic barrier (0.46 eV) of urea adsorption on cellulose, supporting the dissolution mechanism and regeneration behavior. This biodegradable, self-renewable membrane system offers a robust, circular solution for long-term oily wastewater remediation and aligns with green chemistry principles. (Figure presented.).</p>}},
  author       = {{Baig, Nadeem and Ahmad, Tauqir and Sufyan, Ali and Asif, Muhammad Bilal and Alqudaihi, Kawthar and Alrwaily, Balqees and Ahmed, Md Sabbir and Maniruzzaman, Md and Hussain, Arshad and Shah, Syed Shaheen and Larsson, J. Andreas and Aziz, Md Abdul}},
  issn         = {{2059-7037}},
  language     = {{eng}},
  number       = {{1}},
  publisher    = {{Springer Nature}},
  series       = {{npj Clean Water}},
  title        = {{Skin-replaceable antifouling cellulose ceramic membranes from jute agro-waste for sustainable and efficient oily wastewater treatment}},
  url          = {{http://dx.doi.org/10.1038/s41545-025-00538-3}},
  doi          = {{10.1038/s41545-025-00538-3}},
  volume       = {{9}},
  year         = {{2026}},
}

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Skin-replaceable antifouling cellulose ceramic membranes from jute agro-waste for sustainable and efficient oily wastewater treatment