Multi-Column Experimental Test Bed for Xe/Kr Separation

Greenhalgh, Mitchell; Garn, Troy G.; Welty, Amy K.; Lyon, Kevin L.; Watson, Tony

doi:10.2172/1245514

Cited by 2 publications

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“…Xe in particular has been proposed as an anesthetic, , and all three noble gases are used in specialized types of lighting. In addition to these practical uses, the atmospheric detection of Xe is used for monitoring undeclared nuclear tests for the purpose of verification of the Comprehensive Nuclear Test Ban Treaty. , Adsorbents such as metal–organic frameworks (MOFs) are also being considered for the collection of Kr from spent nuclear fuel. − However, finding an efficient and cost-effective method for the capture and separation of noble gases (especially Kr and Xe) from air has proven to be technologically challenging. Generally, the commercial separation of these gases from air involves a cryogenic distillation process that is both energy intensive and expensive.…”

Section: Introductionmentioning

confidence: 99%

Investigating the Effects of Ag, Cu, and Pd Functionalized Chabazite on the Adsorption Affinities of Noble Gases Xe, Kr, and Ar

et al. 2023

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Separation of the noble gases from air is typically done through a cryogenic distillation process that is both energy intensive and expensive. Ag-functionalized zeolites and MOFs have a well-documented affinity for Xe and, to a lesser extent, Kr that could serve as an economical alternative to this process on a commercial scale. The mechanism driving the Ag–Xe interaction, however, is still a matter of debate, and the use of other metals in place of Ag is not as thoroughly documented. In this study, Ag, Cu, and Pd functionalized chabazite specimens were prepared, and their affinities for the noble gases Xe, Kr, and Ar were investigated and compared to each other and an unexchanged Na-chabazite. From these analyses, Ag-functionalized chabazite displayed the highest affinity for Xe among these samples, but there was not a similar affinity for Kr or Ar. From the results, a mechanism is proposed such that the strong Ag–Xe interaction contains both an underlying physical and electronic aspect related to the formation of Ag nanoclusters within the chabazite pore geometry that alters the chabazite surface state such that Xe is preferentially adsorbed.

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Section: Introductionmentioning

confidence: 99%

Investigating the Effects of Ag, Cu, and Pd Functionalized Chabazite on the Adsorption Affinities of Noble Gases Xe, Kr, and Ar

et al. 2023

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“…The results of initial testing of the two column system with AgZ-PAN and HZ-PAN indicate that an excellent separation of Xe from Kr could be attained using the newly installed multi-column system. [1] Building upon these initial results, a series of additional multi-column testing was planned to be performed in FY-16. The purpose of this testing was to scale up the sorbent beds, test a different composition of feed gas and attempt to improve the accuracy of the analysis of the individual capture columns' compositions.…”

Section: Introductionmentioning

confidence: 99%

Multi-Column Xe/Kr Separation with AgZ-PAN and HZ-PAN

Greenhalgh

Garn

Welty

et al. 2016

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Previous multi-column xenon/krypton separation tests demonstrated the capability of separating xenon from krypton in a mixed gas feed stream. The results of this initial testing with AgZ-PAN and HZ-PAN indicated that an excellent separation of xenon from krypton could be achieved. Building upon these initial results, a series of additional multi-column tests were performed in FY-16. The purpose of this testing was to scale up the sorbent beds, test a different composition of feed gas and attempt to improve the accuracy of the analysis of the individual capture columns' compositions.Two Stirling coolers were installed in series to perform this testing. The use of the coolers instead of the cryostat provided two desired improvements, 1) removal of the large dilution due to the internal volume of the cryostat adsorption chamber, and 2) ability to increase the sorbent bed size for scale-up. The AgZ-PAN sorbent, due to its xenon selectivity, was loaded in the first column to capture the xenon while allowing the krypton to flow through and be routed to a second column containing the HZ-PAN for capture and analysis. The gases captured on both columns were sampled with evacuated sample bombs and subsequently analyzed via GC-MS for both krypton and xenon.Preliminary adsorption tests were performed on both sorbents with the feed gas of 400 ppmv Xe and 40 ppmv Kr in a balance of air at the desired temperature and flow rates. Analyses of the results indicated that the krypton column filled with HZ-PAN was the limiting factor for all conditions and the test time could only be 5 hours to avoid any loss of krypton.

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Multi-Column Experimental Test Bed for Xe/Kr Separation

Cited by 2 publications

References 1 publication

Investigating the Effects of Ag, Cu, and Pd Functionalized Chabazite on the Adsorption Affinities of Noble Gases Xe, Kr, and Ar

Investigating the Effects of Ag, Cu, and Pd Functionalized Chabazite on the Adsorption Affinities of Noble Gases Xe, Kr, and Ar

Multi-Column Xe/Kr Separation with AgZ-PAN and HZ-PAN

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