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51. CO2 Acquisition Membrane (CAM)

Author

Mason, Larry W, Way, J. Douglas, and Vlasse, Marcus

Subjects
Nonmetallic Materials
Abstract

The objective of CAM is to develop, test, and analyze thin film membrane materials for separation and purification of carbon dioxide (CO2) from mixtures of gases, such as those found in the Martian atmosphere. The membranes are targeted toward In Situ Resource Utilization (ISRU) applications that will operate in extraterrestrial environments and support future unmanned and human space missions. A primary application is the Sabatier Electrolysis process that uses Mars atmosphere CO2 as raw material for producing water, oxygen, and methane for rocket fuel and habitat support. Other applications include use as an inlet filter to collect and concentrate Mars atmospheric argon and nitrogen gases for habitat pressurization, and to remove CO2 from breathing gases in Closed Environment Life Support Systems (CELSS). CAM membrane materials include crystalline faujasite (FAU) zeolite and rubbery polymers such as silicone rubber (PDMS) that have been shown in the literature and via molecular simulation to favor adsorption and permeation of CO2 over nitrogen and argon. Pure gas permeation tests using commercial PDMS membranes have shown that both CO2 permeance and the separation factor relative to other gases increase as the temperature decreases, and low (Delta)P(Sub CO2) favors higher separation factors. The ideal CO2/N2 separation factor increases from 7.5 to 17.5 as temperature decreases from 22 C to -30 C. For gas mixtures containing CO2, N2, and Ar, plasticization decreased the separation factors from 4.5 to 6 over the same temperature range. We currently synthesize and test our own Na(+) FAU zeolite membranes using standard formulations and secondary growth methods on porous alumina. Preliminary tests with a Na(+) FAU membrane at 22 C show a He/SF6 ideal separation factor of 62, exceeding the Knudsen diffusion selectivity by an order of magnitude. This shows that the membrane is relatively free from large defects and associated non-selective (viscous flow) transport mechanisms. The Membrane Test Facility (MTF) has been developed to measure membrane permeance over a wide range of temperature and pressure. The facility uses two volume compartments separated by the membrane that are instrumented to measure temperature, delta pressure across the membrane, and gas composition. A thermal shroud supports and encloses the membrane, and provides temperature control. Methods were developed to determine membrane permeance using the first order decay of the pressure difference between the sealed compartments, using the total pressure for pure gases, and partial pressure of each species in gas mixtures. The technique provides an end-to-end measurement of gas permeance that includes concentration polarization effects. Experiments have shown that in addition to membrane permeance properties, the geometry and design of associated structures play an important role in how membrane systems will function on Mars.

Published
2003

70. Synthesis of phase pure tungsten carbide for high temperature H2 membranes

Author

Brennan, Karl, Parks, Sterling, Ostwal, Mayur, Way, J. Douglas, and Wolden, Colin Andrew

Subjects
REMRSEC
Abstract

The Pt.-like catalytic behavior of transition metal carbides has been recognized for several decades. However, their potential as robust, highly selective membranes for the steam reforming of methane is only now being realized. The synthesis and properties of molybdenum carbide are well understood and have been previously studied by this research group. This study aims to apply the body of knowledge gained through previous work with Mo2C to investigate a new material: tungsten carbide. This paper aims to develop a robust, reproducible procedure for synthesis of phase-pure tungsten carbides. Greater than 95% of the 50 million tons of H2 produced annually is derived through steam reforming of fossil fuels, which requires energy-intensive separation processes. Membranes offer the potential of significant process simplification and energy reduction, particularly when reforming is combined with the water gas shift reaction and CO2 capture. Carbide composite membranes offer earth abundant alternatives to Pd.

Published
2007
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71. Plasma enhanced chemical vapor deposition synthesis of metal carbide membranes for high temperature H2 separations

Author

Finegan, Donal, Ostwal, Mayur, Way, J. Douglas, and Wolden, Colin Andrew

Subjects
REMRSEC
Abstract

Approximately 80% of the global energy demand comes from fossil fuels and this reliance is expected to increase at least until the year 2020. Combustion of these fossil fuels to generate power produces CO2. Hydrogen gas is a highly sought after chemical within industry and its uses in society are continuously increasing. The annual production of H2 currently stands at around 50 million tonnes. The primary method of production of H2 is steam reforming which produces a gaseous mixture of H2 and CO2. Consequently, methods are sought to separate CO2 and purify H2.

Published
2007
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77. Experimental and Theoretical Insights into the Potential of V2O3Surface Coatings for Hydrogen Permeable Vanadium Membranes

Author

Fuerst, Thomas F., Petsalis, Elias P., Lundin, Sean-Thomas B., Wilcox, Jennifer, Way, J. Douglas, and Wolden, Colin A.

Abstract

A grand challenge of vanadium-based H2permeable membranes is the development of effective, cheap, and stable catalysts to facilitate H2dissociation and recombination. This work investigates a facile air treatment to form catalytically active vanadium oxide on the surfaces of dense vanadium foils. The treatment consisted of short air exposure followed by H2reduction at 823 K, which produced a well-faceted and nanocrystalline V2O3layer on the foil surfaces. The resulting membranes displayed a stable H2permeability of 2 ± 0.25 × 10–8mol·m–1·s–1·Pa–0.5, but transient declines in permeation were observed when operated at both elevated and reduced temperatures. DFT calculations revealed that V2O3(0001) surfaces display barriers and adsorption energies for H2dissociation/recombination that are comparable to those of known H2activation catalysts. It was found that H2dissociation is expected to proceed spontaneously on metal-terminated V2O3, with recombinative-desorption anticipated as the rate limiting step.

Published
2018
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78. Mechanistic Studies of Carrier-Mediated Transport Through Supported Liquid Membranes

Author

Chrisstoffels, Lysander A.J., de Jong, Feike, Reinhoudt, David N., Bartsch, Richard A., and Way, J. Douglas

Subjects
Membrane, Chromatography, biology, Membrane transport protein, Chemistry, Computational chemistry, Diffusion, Phase (matter), Supramolecular chemistry, biology.protein, Molecule, Ionic bonding, Membrane transport
Abstract

Carrier-assisted transport through supported liquid membranes is one of the important applications of supramolecular chemistry. Carriers for the selective transport of neutral molecules, anions, cations or zwitter ionic species have been developed. The transport can be described by subsequent partitioning, complexation and diffusion. Mechanistic studies are mainly focussed on diffusion limited transport, in which diffusion of the complex through the membrane phase is the rate­limiting step of the transport. Recently, kinetic aspects in membrane transport have been elucidated with new carriers for which the rate of decomplexation determines the rate of transport. In this chapter, recent mechanistic aspects for carrier-assisted transport through supported liquid membranes are reviewed.

Published
1996

84. Synthesis of β-Mo2C Thin Films

Author

Wolden, Colin A., primary, Pickerell, Anna, additional, Gawai, Trupti, additional, Parks, Sterling, additional, Hensley, Jesse, additional, and Way, J. Douglas, additional

Published
2011
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