Synthesis, characterization, and performance analysis of carbon molecular sieve-embedded polyethersulfone mixed-matrix membranes for the removal of dissolved ions

Qadir, D. and Nasir, R. and Mukhtar, H.B. and Keong, L.K. (2020) Synthesis, characterization, and performance analysis of carbon molecular sieve-embedded polyethersulfone mixed-matrix membranes for the removal of dissolved ions. Water Environment Research, 92 (9). pp. 1306-1324.

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Abstract

The asymmetric polyethersulfone (PES-15 wt.) mixed-matrix membranes were prepared by incorporation of carbon molecular sieve (CMS) with varying concentrations (1, 3, and 5 wt.). Physicochemical characterization of synthesized membranes was carried out using field emission scanning electron microscope, atomic force microscopy, contact angle, thermogravimetric analysis, zeta potential analyzer, porosity, and mean pore sizes. Performance analysis of synthesized mixed-matrix membranes was carried out by varying the operating parameters such as pressure (2�10 bar), feed concentration (100�1,000 mg/L), and cations type (Na+, Ca2+, Mg2+, and Sn2+). Effect of operating parameters and CMS concentration was investigated on pure water flux (PWF), permeate flux, and rejection of membranes. It was found that mixed-matrix membrane containing 15 wt. PES with 1 wt. CMS displayed the superior physicochemical characteristics in terms of hydrophilicity (37.9°), surface charge (�13.8 mV), mean pore diameter (6.04 nm), and thermal properties (Tg = 218.5°C), and overall performance. E5C1 membrane showed 1.5 times higher PWF (75.5 L m�2 hr�1) and incremented in rejection for all salts than the nascent membrane. Practitioner points: Carbon molecular sieve-embedded mixed-matrix membranes were synthesized by phase inversion method. The resultant membranes experienced improved hydrophilicity, roughness, surface charge, porosity, and mean pore diameter with 1 wt. CMS loading. The pure water flux was improved from 55.77 to 75.05 L m�2 hr�1 when 1 wt. CMS was added in pure PES. The observed rejection of a mixed-matrix membrane with 1 wt. CMS was the maximum for all salts. © 2020 Water Environment Federation

Item Type: Article
Impact Factor: cited By 1
Uncontrolled Keywords: Carbon; Contact angle; Hydrophilicity; Molecular sieves; Physicochemical properties; Pore size; Salts; Scanning electron microscopy; Sieves; Surface charge; Thermogravimetric analysis, Carbon molecular sieve; Field emission scanning electron microscopes; Mixed matrix membranes; Operating parameters; Phase-inversion method; Physico-chemical characterization; Physicochemical characteristics; Zeta potential analyzers, Membranes, calcium; carbon; magnesium; polyethersulfone; sodium; tin; ion; polyethersulfone; polymer; sulfone, concentration (composition); detection method; membrane; molecular analysis; perforation; performance assessment; physicochemical property; pollutant removal; water flux, Article; atomic force microscopy; biodegradability; contact angle; controlled study; field emission scanning electron microscopy; hydrophilicity; light scattering; membrane formation; particle size; physical chemistry; pore size; pore size distribution; porosity; priority journal; room temperature; surface area; surface property; synthesis; thermogravimetry; waste component removal; zeta potential; artificial membrane; membrane, Carbon; Ions; Membranes; Membranes, Artificial; Polymers; Sulfones
Departments / MOR / COE: Research Institutes > Institute for Contaminant Management
Depositing User: PROF IR DR HILMI MUKHTAR
Date Deposited: 25 Mar 2022 03:17
Last Modified: 11 Apr 2023 04:14
URI: http://scholars.utp.edu.my/id/eprint/30004

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