Sudeshna Basu scite author profile

Over the past two decades, membrane processes have gained a lot of attention for the separation of gases. They have been found to be very suitable for wide scale applications owing to their reasonable cost, good selectivity and easily engineered modules. This critical review primarily focuses on the various aspects of membrane processes related to the separation of biogas, more in specific CO(2) and H(2)S removal from CH(4) and H(2) streams. Considering the limitations of inorganic materials for membranes, the present review will only focus on work done with polymeric materials. An overview on the performance of commercial membranes and lab-made membranes highlighting the problems associated with their applications will be given first. The development studies carried out to enhance the performance of membranes for gas separation will be discussed in the subsequent section. This review has been broadly divided into three sections (i) performance of commercial polymeric membranes (ii) performance of lab-made polymeric membranes and (iii) performance of mixed matrix membranes (MMMs) for gas separations. It will include structural modifications at polymer level, polymer blending, as well as synthesis of mixed matrix membranes, for which addition of silane-coupling agents and selection of suitable fillers will receive special attention. Apart from an overview of the different membrane materials, the study will also highlight the effects of different operating conditions that eventually decide the performance and longevity of membrane applications in gas separations. The discussion will be largely restricted to the studies carried out on polyimide (PI), cellulose acetate (CA), polysulfone (PSf) and polydimethyl siloxane (PDMS) membranes, as these membrane materials have been most widely used for commercial applications. Finally, the most important strategies that would ensure new commercial applications will be discussed (156 references).

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MOF-containing mixed-matrix membranes for CO2/CH4 and CO2/N2 binary gas mixture separations

Basu

Cano-Òdena

Vankelecom

2011

Separation and Purification Technology

373

217

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Asymmetric Matrimid®/[Cu3(BTC)2] mixed-matrix membranes for gas separations

Basu

Cano-Òdena

Vankelecom

2010

Journal of Membrane Science

261

182

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Solvent resistant nanofiltration (SRNF) membranes based on metal-organic frameworks

Basu

Maes

Cano-Òdena

et al. 2009

Journal of Membrane Science

254

134

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Helium isotopes in early Iceland plume picrites: Constraints on the composition of high 3He/4He mantle

Starkey

Stuart

Ellam

et al. 2009

Earth and Planetary Science Letters

118

107

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Polyamide thin film composite membranes containing ZIF-8 for the separation of pharmaceutical compounds from aqueous streams

Basu

Balakrishnan

2017

Separation and Purification Technology

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Batch and Continuous Flow Adsorption of Phenolic Compounds from Olive Mill Wastewater: A Comparison between Nonionic and Ion Exchange Resins

Pinelli

Bacca

Kaushik

et al. 2016

International Journal of Chemical Engineering

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The goals of this work were (i) to compare two anion ion exchange resins (IRA958 Cl and IRA67) and a nonionic resin (XAD16) in terms of phenolic compounds adsorption capacity from olive mill wastewater and (ii) to compare the adsorption capacity of the best resin on columns of different length. The ion exchange resins performed worse than nonionic XAD16 in terms of resin utilization efficiency (20% versus 43%) and phenolic compounds/COD enrichment factor (1.0 versus 2.5). The addition of volatile fatty acids did not hinder phenolic compounds adsorption on either resin, suggesting a noncompetitive adsorption mechanism. A pH increase from 4.9 to 7.2 did not affect the result of this comparison. For the best performing resin (XAD16), an increase in column length from 0.5 to 1.8 m determined an increase in resin utilization efficiency (from 12% to 43%), resin productivity (from 3.4 to 7.6 g sorbed phenolics /kg resin ), and phenolics/COD enrichment factor (from 1.2 to 2.5). An axial dispersion model with nonequilibrium adsorption accurately interpreted the phenolic compounds and COD experimental curves.

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Forward Osmosis in Wastewater Treatment Processes

Korenak¹,

Basu²,

Balakrishnan³

et al. 2017

ACSi

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In recent years, membrane technology has been widely used in wastewater treatment and water purification. Membrane technology is simple to operate and produces very high quality water for human consumption and industrial purposes. One of the promising technologies for water and wastewater treatment is the application of forward osmosis. Essentially, forward osmosis is a process in which water is driven through a semipermeable membrane from a feed solution to a draw solution due to the osmotic pressure gradient across the membrane. The immediate advantage over existing pressure driven membrane technologies is that the forward osmosis process per se eliminates the need for operation with high hydraulic pressure and forward osmosis has low fouling tendency. Hence, it provides an opportunity for saving energy and membrane replacement cost. However, there are many limitations that still need to be addressed. Here we briefly review some of the applications within water purification and new developments in forward osmosis membrane fabrication.

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Sudeshna Basu

Membrane-based technologies for biogas separations

MOF-containing mixed-matrix membranes for CO2/CH4 and CO2/N2 binary gas mixture separations

Asymmetric Matrimid®/[Cu3(BTC)2] mixed-matrix membranes for gas separations

Solvent resistant nanofiltration (SRNF) membranes based on metal-organic frameworks

Helium isotopes in early Iceland plume picrites: Constraints on the composition of high 3He/4He mantle

Polyamide thin film composite membranes containing ZIF-8 for the separation of pharmaceutical compounds from aqueous streams

Batch and Continuous Flow Adsorption of Phenolic Compounds from Olive Mill Wastewater: A Comparison between Nonionic and Ion Exchange Resins

Forward Osmosis in Wastewater Treatment Processes

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