High Pressure Excess Isotherms for Adsorption of Oxygen and Nitrogen in Zeolites

Wang, Yu; Helvensteijn, Bernardus P.; Nizamidin, Nabijan; Erion, Angelae M.; Steiner, Laura A.; Mulloth, Lila; Luna, Bernadette; LeVan, M. Douglas

doi:10.1021/la201690x

Cited by 24 publications

(26 citation statements)

References 42 publications

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“…1a,7,8 In contrast, studies pertaining to high-pressure oxygen (O 2 ) storage are still scarce. 9 The availability of high amounts of O 2 is of prime importance in the health care domain, particularly in the treatment of respiratory insufficiencies and in hyperbaric oxygen changes for the treatment of carbon monoxide poisoning. Correspondingly, a large amount of oxygen is used to enrich air during catalyst regeneration in the catalytic cracking units.…”

Section: Introductionmentioning

confidence: 99%

MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based soc-MOF for CH₄, O₂, and CO₂ Storage

Alezi¹,

Belmabkhout²,

Suyetin³

et al. 2015

J. Am. Chem. Soc.

709

361

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The molecular building block approach was employed effectively to construct a series of novel isoreticular, highly porous and stable, aluminum-based metal–organic frameworks with soc topology. From this platform, three compounds were experimentally isolated and fully characterized: namely, the parent Al-soc-MOF-1 and its naphthalene and anthracene analogues. Al-soc-MOF-1 exhibits outstanding gravimetric methane uptake (total and working capacity). It is shown experimentally, for the first time, that the Al-soc-MOF platform can address the challenging Department of Energy dual target of 0.5 g/g (gravimetric) and 264 cm3 (STP)/cm3 (volumetric) methane storage. Furthermore, Al-soc-MOF exhibited the highest total gravimetric and volumetric uptake for carbon dioxide and the utmost total and deliverable uptake for oxygen at relatively high pressures among all microporous MOFs. In order to correlate the MOF pore structure and functionality to the gas storage properties, to better understand the structure–property relationship, we performed a molecular simulation study and evaluated the methane storage performance of the Al-soc-MOF platform using diverse organic linkers. It was found that shortening the parent Al-soc-MOF-1 linker resulted in a noticeable enhancement in the working volumetric capacity at specific temperatures and pressures with amply conserved gravimetric uptake/working capacity. In contrast, further expansion of the organic linker (branches and/or core) led to isostructural Al-soc-MOFs with enhanced gravimetric uptake but noticeably lower volumetric capacity. The collective experimental and simulation studies indicated that the parent Al-soc-MOF-1 exhibits the best compromise between the volumetric and gravimetric total and working uptakes under a wide range of pressure and temperature conditions.

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Section: Introductionmentioning

confidence: 99%

MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based soc-MOF for CH₄, O₂, and CO₂ Storage

Alezi¹,

Belmabkhout²,

Suyetin³

et al. 2015

J. Am. Chem. Soc.

709

361

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“…22 The adsorption and diffusion of alkanes have also been widely studied in both pure silica and alumino-substituted zeolites. 9, 11,13,17,21,24,[31][32][33][34][35][36][37] Despite current efforts, the development of transferable force fields for describing the adsorption in zeolites (especially at low temperatures) remains a complex task. 22,[26][27][28][29][30] The adsorption and diffusion of other small gases such as nitrogen, argon, oxygen, or carbon monoxide have also been reported in zeolites but in lesser amount.…”

Section: Introductionmentioning

confidence: 99%

Transferable force fields for adsorption of small gases in zeolites

Martín-Calvo

Gutiérrez‐Sevillano

Parra

et al. 2015

Phys. Chem. Chem. Phys.

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We provide transferable force fields for oxygen, nitrogen, and carbon monoxide that are able to reproduce experimental adsorption in both pure silica and alumino-substituted zeolites at cryogenic and high temperatures. The force field parameters can be combined with those previously reported for carbon dioxide, methane, and argon, opening the possibility for studying mixtures of interest containing the six components. Using these force field parameters we obtained some adsorption isotherms at cryogenic temperatures that at first sight were in discrepancies with experimental values for certain molecules and structures. We attribute these discrepancies to the sensitiveness of the equipment and to kinetic impedimenta that can lead to erratic results. Additional problems can be found during simulations when extra-framework cations are present in the system as their lack of mobility at low temperatures could lead to kinetic effects that hinder experimental adsorption.

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“…NIST's REFPROP extension to MS Excel was applied to determine densities (quoted accuracy of 0.1% of value). The ARC data reported here is the volumetrically measured absolute adsorption as opposed to the excess adsorption reported by Wang et al 6 …”

Section: Approachmentioning

confidence: 95%

“…Pressures range up to about 15 MPa (2200 psia) though limited by the saturation pressure where applicable. The VU group has set out to measure oxygen adsorption at higher temperatures (from 250 K to 430 K) 6 .…”

Section: Project Reachmentioning

confidence: 99%

Adsorption of oxygen onto zeolites at pressures up to 15 MPa

Helvensteijn¹,

Wang²,

LeVan³

et al. 2012

AIP Conference Proceedings

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For NASA applications, high-pressure oxygen is an integral part of portable life support systems (PLSSs) for Extravehicular Activities (EVAs), some fuel cell systems and potential In Situ Resource Utilization (ISRU) systems. New high-pressure oxygen generation systems will be needed on the International Space Station (to enable EVAs after the Shuttle is retired), on a Lunar Lander (to use lower pressure cryogenic tanks as a source of high pressure oxygen for EVAs) and on a planetary habitat (to generate and store high pressure oxygen for extended periods of time). One of the candidate technologies for producing high-pressure oxygen, temperature swing adsorption (TSA) compression, offers many advantages but has a low technology readiness level. Evaluation of technical feasibility and safety issues, and specification of operating parameters of the compressor require the availability of fundamental equilibrium adsorption data. A cryogenic, highpressure volumetric equilibrium adsorption apparatus has been developed at NASA Ames Research Center to facilitate collection of the needed data. The apparatus incorporates cryogenic and vacuum surrounds, and a high-pressure oxygen circuit. In this paper, lowtemperature equilibrium isotherms of oxygen on various sorbent materials are presented. The data presented will aid the development of a space qualified TSA system.

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High Pressure Excess Isotherms for Adsorption of Oxygen and Nitrogen in Zeolites

Cited by 24 publications

References 42 publications

MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based soc-MOF for CH₄, O₂, and CO₂ Storage

MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based soc-MOF for CH₄, O₂, and CO₂ Storage

Transferable force fields for adsorption of small gases in zeolites

Adsorption of oxygen onto zeolites at pressures up to 15 MPa

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High Pressure Excess Isotherms for Adsorption of Oxygen and Nitrogen in Zeolites

Cited by 24 publications

References 42 publications

MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based soc-MOF for CH4, O2, and CO2 Storage

MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based soc-MOF for CH4, O2, and CO2 Storage

Transferable force fields for adsorption of small gases in zeolites

Adsorption of oxygen onto zeolites at pressures up to 15 MPa

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Product

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MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based soc-MOF for CH₄, O₂, and CO₂ Storage

MOF Crystal Chemistry Paving the Way to Gas Storage Needs: Aluminum-Based soc-MOF for CH₄, O₂, and CO₂ Storage