Improving water desalination: Sustainable grafted cellulose acetate reverse osmosis membrane from Egyptian cotton-Reference-Cited by-同舟云学术

Improving water desalination: Sustainable grafted cellulose acetate reverse osmosis membrane from Egyptian cotton

Published:2024-03-11 Issue:5 Volume:64 Page:2278-2288
ISSN:0032-3888
Container-title:Polymer Engineering & Science
language:en
Short-container-title:Polymer Engineering & Sci

Author:

Zhang Hong¹²,Morsy Ashraf³⁴^ORCID,Kandil S.³,Ewais Hassan A.⁵,Abdel‐Salam Ahmed H.⁶,Kenawy E.⁷,Yousef N. S.⁴,Shokry F.⁸,Abdel‐Fattah Tarek M.⁹,Ebrahim Sh.³

Affiliation:

1. Management School, China University of Mining and Technology (Beijing) China

2. Shenhua Engineering Technology Co. Ltd Beijing China

3. Materials Science Department, Institute of Graduate Studies & Research Alexandria University Alexandria Egypt

4. Petrochemicals Department, Faculty of Engineering Pharos University Alexandria Egypt

5. Chemistry Department, Faculty of Science King Abdulaziz University Jeddah Saudi Arabia

6. Chemistry Department, Faculty of Science University of Jeddah Jeddah Saudi Arabia

7. Chemistry Department, Faculty of Science Tanta University Tanta Egypt

8. Chemical Engineering Department, Faculty of Engineering Portsaid Egypt

9. Applied Research Center, Thomas Jefferson National Accelerator Facility and Department of Molecular Biology and Chemistry Christopher Newport University Newport News Virginia USA

Abstract

AbstractCellulose diacetate (CDA) and triacetate (CTA) were derived from Egyptian cotton to fabricate reverse osmosis (RO) membranes. The Pphase inversion method was utilized for the production of CDA‐based membranes. Comprehensive characterization of these membranes involved structural, morphologial, and hydrophilic property analyses through techniques such as nuclear magnetic resonance (NMR), infrared spectroscopy, thermal gravimetric analysis (TGA), scanning electron microscopy (SEM), atomic force microscopy (AFM), and contact angle measurements. NMR spectra indicated a degree of substitution of 2.9 for CTA and 2 for CDA. The resulting RO membrane demonstrated a water flux of 6.1 L/m2·h and a salt rejection of 90.3%. Annealing led to an enhanced top layer with reduced defects and macrovoids in the support layer. Moreover, grafting the RO membranes with 15 wt% of 2‐acrylamidopropane‐2‐methyl sulphonic acid improved salt rejection to 96.2% and water flux to 8.7 L/m2.h. These findings underscore the significant performance enhancements achieved through both annealing and grafting processes in RO membranes.

Publisher

Wiley

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