Multifunctional Purification and Sensing of Toxic Hydride Gases by CuBTC Metal–Organic Framework

In this report, we evaluate the metal–organic framework CuBTC as a real-world adsorbent for protection against three toxic hydride gases: ammonia, arsine, and hydrogen sulfide. We develop a scalable room-temperature synthesis of high-surface-area CuBTC using a benign ethanol–water solvent system. We...

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Veröffentlicht in:	Industrial & engineering chemistry research 2015-04, Vol.54 (14), p.3626-3633
Hauptverfasser:	Peterson, Gregory W, Britt, David K, Sun, Daniel T, Mahle, John J, Browe, Matthew, Demasky, Tyler, Smith, Shirmonda, Jenkins, Amanda, Rossin, Joseph A
Format:	Artikel
Sprache:	eng
Schlagworte:	Adsorbents Ammonia Detection Hydrides Hydrogen sulfide Metal-organic frameworks Toxic Toxicology Uptakes
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creator	Peterson, Gregory W Britt, David K Sun, Daniel T Mahle, John J Browe, Matthew Demasky, Tyler Smith, Shirmonda Jenkins, Amanda Rossin, Joseph A
description	In this report, we evaluate the metal–organic framework CuBTC as a real-world adsorbent for protection against three toxic hydride gases: ammonia, arsine, and hydrogen sulfide. We develop a scalable room-temperature synthesis of high-surface-area CuBTC using a benign ethanol–water solvent system. We test the capacity of CuBTC for the hydride gases under microbreakthrough and real-world packed-bed conditions at both low and high humidity conditions. Under microbreakthrough conditions, CuBTC outperforms a broad-spectrum carbon (BSC) adsorbent for uptake of ammonia and arsine, with approximately equivalent uptake of hydrogen sulfide. Under packed-bed conditions, CuBTC outperforms the BSC for ammonia uptake but offers little protection against arsine or hydrogen sulfide. We demonstrate the potential for CuBTC to act not only as an effective adsorbent for ammonia but also for sensing and to indicate saturation on the basis of colorimetric and fluorescence changes. We find that CuBTC is a suitable material for inclusion in respiratory protective devices for protection against ammonia, with potential benefits against other hydride gases.
doi_str_mv	10.1021/acs.iecr.5b00458
format	Article
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Eng. Chem. Res</addtitle><date>2015-04-15</date><risdate>2015</risdate><volume>54</volume><issue>14</issue><spage>3626</spage><epage>3633</epage><pages>3626-3633</pages><issn>0888-5885</issn><eissn>1520-5045</eissn><abstract>In this report, we evaluate the metal–organic framework CuBTC as a real-world adsorbent for protection against three toxic hydride gases: ammonia, arsine, and hydrogen sulfide. We develop a scalable room-temperature synthesis of high-surface-area CuBTC using a benign ethanol–water solvent system. We test the capacity of CuBTC for the hydride gases under microbreakthrough and real-world packed-bed conditions at both low and high humidity conditions. Under microbreakthrough conditions, CuBTC outperforms a broad-spectrum carbon (BSC) adsorbent for uptake of ammonia and arsine, with approximately equivalent uptake of hydrogen sulfide. 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subjects	Adsorbents Ammonia Detection Hydrides Hydrogen sulfide Metal-organic frameworks Toxic Toxicology Uptakes
title	Multifunctional Purification and Sensing of Toxic Hydride Gases by CuBTC Metal–Organic Framework
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