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Effect of MAX Phase Ti3ALC2 on the Ultrafiltration Membrane Properties and Performance

Tamara Wahid AboodDepartment of Materials Engineering, University of Technology-Iraq, Alsinaa Street 52, Baghdad 10066, IraqKadhum M. ShabeebDepartment of Materials Engineering, University of Technology-Iraq, Alsinaa Street 52, Baghdad 10066, IraqAseel B. AlzubaydiDepartment of Materials Engineering, University of Technology-Iraq, Alsinaa Street 52, Baghdad 10066, IraqHasan Sh. MajdiDepartment of Chemical Engineering and Petroleum Industries, AlMustaqbal University College, Babylon 51001, IraqRaed A. Al-JubooriNYUAD Water Research Centre, Abu Dhabi Campus, New York University, Abu Dhabi P.O. Box 129188, United Arab EmiratesQusay F. AlsalhyMembrane Technology Research Unit, Department of Chemical Engineering, University of Technology-Iraq, Alsinaa Street 52, Baghdad 10066, Iraq
2023en
ABI

Abstract

Membrane fouling remains a major obstacle to ultrafiltration. Due to their effectiveness and minimal energy demand, membranes have been extensively employed in water treatment. To improve the antifouling property of the PVDF membrane, a composite ultrafiltration membrane was created employing the in-situ embedment approach throughout the phase inversion process and utilizing a new 2D material, MAX phase Ti3ALC2. The membranes were described using FTIR (Fourier transform infrared spectroscopy), EDS (energy dispersive spectroscopy), CA (water contact angle), and porosity measurements. Additionally, atomic force microscopy (AFM), field emission scanning electron microscopy (FESEM), and energy dispersive spectroscopy (EDS) were employed. Standard flux and rejection tests were applied to study the produced membranes’ performance. Adding Ti3ALC2 reduced composite membranes’ surface roughness and hydrophobicity compared to the pristine membrane. Porosity and membrane pore size increased with the addition up to 0.3% w/v, which decreased as the additive percentage increased. The mixed matric membrane with 0.7% w/v of Ti3ALC2 (M7) had the lowest CA. The alteration in the membranes’ properties reflected well on their performance. The membrane with the highest porosity (0.1% w/v of Ti3ALC2, M1) achieved the highest pure water and protein solution fluxes of 182.5 and 148.7. The most hydrophilic membrane (M7) recorded the highest protein rejection and flux recovery ratio of 90.6, which was much higher than that of the pristine membrane, 26.2. MAX phase Ti3ALC2 is a potential material for antifouling membrane modification because of its protein permeability, improved water permeability, and outstanding antifouling characteristics.

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