Iodine Vapor Reactions with Pure Metal Wires at Temperatures of 100–139 °C in Air

Riley, Brian J.; Chong, Saehwa; Beck, Chelsie L.

doi:10.1021/acs.iecr.1c03902

Cited by 16 publications

(37 citation statements)

References 47 publications

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“…The environmental stability of the metal iodide formed after capture considers the chemical surface reactivity and morphological changes that could occur during operation and upon long-term storage after capture ( Figure 1E ). Some examples of where this is important were documented in a recent paper by Riley et al (2021) where some of the highest performing pure metals for I 2(g) capture were indium (forming InI 3 ) and tin (forming SnI 4 ). While In and Sn metals have a tremendous affinity for I 2(g) forming a triiodide and tetraiodide (i.e., 76.8 and 81.0 mass% iodine, shown in Figure 2B ), respectively, neither MI x complex is environmentally stable.…”

Section: Introductionmentioning

confidence: 98%

“… Summary of various parameters for consideration when selecting sorbents for radioiodine: (A) optimal capture performance including different types of Ag-zeolites that have different Ag loadings ( Riley et al, 2022b ) (criterion-1), (B) sorbent kinetics including examples based off actual data for I 2 ( Riley et al, 2014 ) for sulfide-based chalcogels and CH 3 I for Ag 0 -aerogels ( Tang et al, 2021 ) [in parts per billion by volume (ppbv) CH 3 I concentration streams] (criterion-2), (C) performance under relevant conditions based off data for I/Cl coadsorption ( Matyáš et al, 2021b ) and other studies in this area ( Riley et al, 2021 ; Riley et al, 2022a ) (criterion-3), (D) inherent properties of sorbent substrate ( Riley et al, 2021 ) (criterion-4), and (E) iodide stability and disposition pathways ( Riley et al, 2021 ; Reiser et al, 2022 ) (criterion-5). …”

Section: Introductionmentioning

confidence: 99%

“…Figure 2 shows some of the elements that have been explored in various forms for the capture of volatile iodine along with the expected MO y I x compounds based on expected metal oxidation states in the iodine-loaded complexes ( Maeck et al, 1968 ; Maeck and Pence 1970 ; Pence et al, 1970 ; Pence et al, 1972 ; Matyáš et al, 2011 ; Riley et al, 2017 ; Riley et al, 2020 ; Matyáš et al, 2021a ; Riley et al, 2021 ; Tesfay Reda et al, 2021 ). In practice, several of these base metals do not show iodine capture under saturated conditions so specialized conditions might be needed to realize their potential ( Riley et al, 2021 ). Figure 2B provides an overview of the large range in maximum iodine loadings possible by simply selecting different getter metals.…”

Section: Introductionmentioning

confidence: 99%

“…Studies examining alternative metals have typically incorporated them into oxide-based [e.g., zeolites ( Maeck and Pence 1970 ; Pence et al, 1972 ), silica ( Matyáš et al, 2011 ; Riley et al, 2017 ; Riley et al, 2020 )] or carbon-based ( Muhire et al, 2022 ) substrates. As the choices of substrate and getter loading method can affect iodine capture, a recent study was conducted using pure metallic substrates to eliminate these artifacts ( Riley et al, 2021 ). This study demonstrated that silver, and other pure metals such as Al 0 , Cu 0 , In 0 , and Sn 0 can be used to capture large quantities of iodine in saturated conditions at various temperatures.…”

Section: Introductionmentioning

confidence: 99%

“…In the reprocessing of used nuclear fuel, extremes in pH are observed depending on the process, such as acidic pH conditions [e.g., HNO 3(g) , HF (g) ] in off-gas streams or highly basic pH conditions in a caustic scrubber solution or a molten hydroxide scrubber (i.e., pH ≥ 12) ( Riley et al, 2016 ). It is also an issue if the stability of the sorbent varies with temperature as some metals behave differently at low temperatures versus high temperatures ( Riley et al, 2021 ). An additional point is that the performance of different getters can vary in terms of their abilities to scavenge low concentrations of the target species from a larger volume of competing species (e.g., Cl 2 ) ( Matyáš et al, 2021b ).…”

Section: Introductionmentioning

confidence: 99%

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Radioiodine sorbent selection criteria

Riley

Carlson

2022

Front. Chem.

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Methods for preventing radioiodine from entering the environment are needed in processes related to nuclear energy and medical isotope production. The development and performance of many different types of sorbents to capture iodine have been reported on for decades; however, there is yet to be a concise overview on the important parameters that should be considered when selecting a material for chemically capturing radioiodine. This paper summarizes several criteria that should be considered when selecting candidate sorbents for implementation into real-world systems. The list of selection criteria discussed are 1) optimal capture performance, 2) kinetics of adsorption, 3) performance under relevant process conditions, 4) properties of the substrate that supports the getter, and 5) environmental stability and disposition pathways for iodine-loaded materials.

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Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Radioiodine sorbent selection criteria

Riley

Carlson

2022

Front. Chem.

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Cluster‐Based Crystalline Materials for Iodine Capture

Wang

Liu

Zhang

et al. 2022

Chemistry A European J

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The treatment of radioactive iodine in nuclear waste has always been a critical issue of social concern. The rational design of targeted and efficient capture materials is of great significance to the sustainable development of the ecological environment. In recent decades, crystalline materials have served as a molecular platform to study the binding process and capture mechanism of iodine molecules, enabling people to understand the interaction between radioactive iodine guests and pores intuitively. Cluster‐based crystalline materials, including molecular clusters and cluster‐based metal‐organic frameworks, are emerging candidates for iodine capture due to their aggregative binding sites, precise structural information, tunable pores/packing patterns, and abundant modifications. Herein, recent progress of different types of cluster materials and cluster‐dominated metal‐organic porous materials for iodine capture is reviewed. Research prospects, design strategies to improve the affinity for iodine and possible capture mechanisms are discussed.

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Hollow Core–Shell Bismuth Based Al‐Doped Silica Materials for Powerful Co‐Sequestration of Radioactive I₂ and CH₃I

Tian,

Hao,

Chee

et al. 2023

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Developing pure inorganic materials capable of efficiently co‐removing radioactive I2 and CH3I has always been a major challenge. Bismuth‐based materials (BBMs) have garnered considerable attention due to their impressive I2 sorption capacity at high‐temperature and cost‐effectiveness. However, solely relying on bismuth components falls short in effectively removing CH3I and has not been systematically studied. Herein, a series of hollow mesoporous core–shell bifunctional materials with adjustable shell thickness and Si/Al ratio by using silica‐coated Bi2O3 as a hard template and through simple alkaline‐etching and CTAB‐assisted surface coassembly methods (Bi@Al/SiO2) is successfully synthesized. By meticulously controlling the thickness of the shell layer and precisely tuning of the Si/Al ratio composition, the synthesis of BBMs capable of co‐removing radioactive I2 and CH3I for the first time, demonstrating remarkable sorption capacities of 533.1 and 421.5 mg g−1, respectively is achieved. Both experimental and theoretical calculations indicate that the incorporation of acid sites within the shell layer is a key factor in achieving effective CH3I sorption. This innovative structural design of sorbent enables exceptional co‐removal capabilities for both I2 and CH3I. Furthermore, the core–shell structure enhances the retention of captured iodine within the sorbents, which may further prevent potential leakage.

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Iodine Vapor Reactions with Pure Metal Wires at Temperatures of 100–139 °C in Air

Cited by 16 publications

References 47 publications

Radioiodine sorbent selection criteria

Radioiodine sorbent selection criteria

Cluster‐Based Crystalline Materials for Iodine Capture

Hollow Core–Shell Bismuth Based Al‐Doped Silica Materials for Powerful Co‐Sequestration of Radioactive I₂ and CH₃I

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Iodine Vapor Reactions with Pure Metal Wires at Temperatures of 100–139 °C in Air

Cited by 16 publications

References 47 publications

Radioiodine sorbent selection criteria

Radioiodine sorbent selection criteria

Cluster‐Based Crystalline Materials for Iodine Capture

Hollow Core–Shell Bismuth Based Al‐Doped Silica Materials for Powerful Co‐Sequestration of Radioactive I2 and CH3I

Contact Info

Product

Resources

About

Hollow Core–Shell Bismuth Based Al‐Doped Silica Materials for Powerful Co‐Sequestration of Radioactive I₂ and CH₃I