Abstract
Membrane science is a state-of-the-art environmentally green technology that ascertains superior advantages over traditional counterparts for CO2 capture and separation. In this research, mixed matrix membranes (MMMs) comprising cellulose acetate (CA) with various loadings of bentonite (Bt) clay were fabricated by adopting the phase-inversion technique for CO2/CH4 and CO2/N2 separation. The developed pristine and MMMs were characterized for morphological, thermal, structural, and mechanical analyses. Several techniques such as scanning electron microscopy, thermogravimetric analysis, Fourier transformed infrared spectroscopy, and nano-indentation investigations revealed the promising effect of Bt clay in MMMs as compared to pristine CA membrane. Nano-indentation test identified that elastic modulus and hardness of the MMM with 1 wt. loading was increased by 64% and 200%, respectively, compared to the pristine membrane. The permeability decreased with the incorporation of Bt clay due to uniform dispersion of filler attributed to enhanced tortuosity for the gas molecules. Nevertheless, an increase in gas separation performance was observed with Bt addition up to 1 wt. loading. The opposite trend prevailed with increasing Bt concentration on the separation performance owing to filler agglomeration and voids creation. The maximum value of ideal selectivity (CO2/CH4) was achieved at 2 bar pressure with 1 wt. % Bt loading, which is 79% higher than the pristine CA membrane. For CO2/N2, the ideal selectivity was 123% higher compared to the pristine membrane with 1 wt. % Bt loading at 4 bar pressure.
Highlights
Nowadays, it is widely conceded and understood that CO2 emission is the pivotal reason behind climate changes, ocean acidification, and associated global warming
The potential of bentonite clay (Bt) as the inorganic filler has been investigated in cellulose acetate (CA) membranes
The phase-inversion technique was adopted for the fabrication of pristine CA membrane as well as matrix membranes (MMMs) with various Bt loadings in the CA matrix
Summary
It is widely conceded and understood that CO2 emission is the pivotal reason behind climate changes, ocean acidification, and associated global warming. CO2 separation is inevitable, and efforts are underway at limited scale compared to what is required Several techniques such as absorption, cryogenic distillation, and adsorption are used frequently to separate and capture CO2 gas. Inappropriate selection of materials may lead to interfacial defects and seriously damage the separation capacity of MMMs. successful membrane formation is subject to the selection of compatible polymer filler systems. Clay minerals are characterized as earthy, fine-grained natural soil materials, and extensively studied as inorganic filler in polymer composite industry [15]. Exfoliated morphology is the most desired one and offers uniform distribution that promotes gas separation performance in MMM [19, 20]. CA is extensively studied as organic phase for polymeric and nano-composite gas separation membranes; its potential with bentonite clay incorporation is barely reported. Gas separation (CO2/N2 and CO2/CH4) study was performed for the developed membranes
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