Iodine immobilization by materials through sorption and redox-driven processes: A literature review

Radioiodine-129 (129I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to compile information on materials that could potentially be used to immobilize 129I through sorption and redox-driven processes, with an emphasis on...

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Published inThe Science of the total environment Vol. 716; p. 132820
Main Authors Moore, Robert C., Pearce, Carolyn I., Morad, Joseph W., Chatterjee, Sayandev, Levitskaia, Tatiana G., Asmussen, Robert M., Lawter, Amanda R., Neeway, James J., Qafoku, Nikolla P., Rigali, Mark J., Saslow, Sarah A., Szecsody, Jim E., Thallapally, Praveen K., Wang, Guohui, Freedman, Vicky L.
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 10.05.2020
Subjects
activated carbon
aerogels
Bismuth-based materials
coordination polymers
environmental impact
hydroxides
Hydroxyapatite
Iodine
ion exchange resins
iron
Iron oxides
Layered double hydroxides
Metal organic frameworks
minerals
radionuclides
solubility
Sorbents
sorption
Subsurface contamination
Bismuth-based materials
Metal organic frameworks
Sorbents
Subsurface contamination
Hydroxyapatite
Iron oxides
Iodine
Layered double hydroxides
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Abstract Radioiodine-129 (129I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to compile information on materials that could potentially be used to immobilize 129I through sorption and redox-driven processes, with an emphasis on ex-situ processes. Candidate materials to immobilize 129I include iron minerals, sulfur-based materials, silver-based materials, bismuth-based materials, ion exchange resins, activated carbon, modified clays, and tailored materials (metal organic frameworks (MOFS), layered double hydroxides (LDHs) and aerogels). Where available, compiled information includes material performance in terms of (i) capacity for 129I uptake; (ii) long-term performance (i.e., solubility of a precipitated phase); (iii) technology maturity; (iv) cost; (v) available quantity; (vi) environmental impact; (vii) ability to emplace the technology for in situ use at the field-scale; and (viii) ex situ treatment (for media extracted from the subsurface or secondary waste streams). Because it can be difficult to compare materials due to differences in experimental conditions applied in the literature, materials will be selected for subsequent standardized batch loading tests. [Display omitted] •Iodine immobilization processes include precipitation, sorption or encapsulation.•Fe, Cu & Bi materials sorb iodine species & are useful for remediation.•Bi materials are readily available, inexpensive & insensitive to redox processes.•IX resins, activated carbon & organoclays are effective sorbants for I− but not IO3−.•MOFs, LDHs & aerogels require further investigation for iodine immobilization.
AbstractList Radioiodine-129 (129I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to compile information on materials that could potentially be used to immobilize 129I through sorption and redox-driven processes, with an emphasis on ex-situ processes. Candidate materials to immobilize 129I include iron minerals, sulfur-based materials, silver-based materials, bismuth-based materials, ion exchange resins, activated carbon, modified clays, and tailored materials (metal organic frameworks (MOFS), layered double hydroxides (LDHs) and aerogels). Where available, compiled information includes material performance in terms of (i) capacity for 129I uptake; (ii) long-term performance (i.e., solubility of a precipitated phase); (iii) technology maturity; (iv) cost; (v) available quantity; (vi) environmental impact; (vii) ability to emplace the technology for in situ use at the field-scale; and (viii) ex situ treatment (for media extracted from the subsurface or secondary waste streams). Because it can be difficult to compare materials due to differences in experimental conditions applied in the literature, materials will be selected for subsequent standardized batch loading tests.Radioiodine-129 (129I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to compile information on materials that could potentially be used to immobilize 129I through sorption and redox-driven processes, with an emphasis on ex-situ processes. Candidate materials to immobilize 129I include iron minerals, sulfur-based materials, silver-based materials, bismuth-based materials, ion exchange resins, activated carbon, modified clays, and tailored materials (metal organic frameworks (MOFS), layered double hydroxides (LDHs) and aerogels). Where available, compiled information includes material performance in terms of (i) capacity for 129I uptake; (ii) long-term performance (i.e., solubility of a precipitated phase); (iii) technology maturity; (iv) cost; (v) available quantity; (vi) environmental impact; (vii) ability to emplace the technology for in situ use at the field-scale; and (viii) ex situ treatment (for media extracted from the subsurface or secondary waste streams). Because it can be difficult to compare materials due to differences in experimental conditions applied in the literature, materials will be selected for subsequent standardized batch loading tests.
Radioiodine-129 (129I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to compile information on materials that could potentially be used to immobilize 129I through sorption and redox-driven processes, with an emphasis on ex-situ processes. Candidate materials to immobilize 129I include iron minerals, sulfur-based materials, silver-based materials, bismuth-based materials, ion exchange resins, activated carbon, modified clays, and tailored materials (metal organic frameworks (MOFS), layered double hydroxides (LDHs) and aerogels). Where available, compiled information includes material performance in terms of (i) capacity for 129I uptake; (ii) long-term performance (i.e., solubility of a precipitated phase); (iii) technology maturity; (iv) cost; (v) available quantity; (vi) environmental impact; (vii) ability to emplace the technology for in situ use at the field-scale; and (viii) ex situ treatment (for media extracted from the subsurface or secondary waste streams). Because it can be difficult to compare materials due to differences in experimental conditions applied in the literature, materials will be selected for subsequent standardized batch loading tests. [Display omitted] •Iodine immobilization processes include precipitation, sorption or encapsulation.•Fe, Cu & Bi materials sorb iodine species & are useful for remediation.•Bi materials are readily available, inexpensive & insensitive to redox processes.•IX resins, activated carbon & organoclays are effective sorbants for I− but not IO3−.•MOFs, LDHs & aerogels require further investigation for iodine immobilization.
Radioiodine-129 ( I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to compile information on materials that could potentially be used to immobilize I through sorption and redox-driven processes, with an emphasis on ex-situ processes. Candidate materials to immobilize I include iron minerals, sulfur-based materials, silver-based materials, bismuth-based materials, ion exchange resins, activated carbon, modified clays, and tailored materials (metal organic frameworks (MOFS), layered double hydroxides (LDHs) and aerogels). Where available, compiled information includes material performance in terms of (i) capacity for I uptake; (ii) long-term performance (i.e., solubility of a precipitated phase); (iii) technology maturity; (iv) cost; (v) available quantity; (vi) environmental impact; (vii) ability to emplace the technology for in situ use at the field-scale; and (viii) ex situ treatment (for media extracted from the subsurface or secondary waste streams). Because it can be difficult to compare materials due to differences in experimental conditions applied in the literature, materials will be selected for subsequent standardized batch loading tests.
Radioiodine-129 (¹²⁹I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to compile information on materials that could potentially be used to immobilize ¹²⁹I through sorption and redox-driven processes, with an emphasis on ex-situ processes. Candidate materials to immobilize ¹²⁹I include iron minerals, sulfur-based materials, silver-based materials, bismuth-based materials, ion exchange resins, activated carbon, modified clays, and tailored materials (metal organic frameworks (MOFS), layered double hydroxides (LDHs) and aerogels). Where available, compiled information includes material performance in terms of (i) capacity for ¹²⁹I uptake; (ii) long-term performance (i.e., solubility of a precipitated phase); (iii) technology maturity; (iv) cost; (v) available quantity; (vi) environmental impact; (vii) ability to emplace the technology for in situ use at the field-scale; and (viii) ex situ treatment (for media extracted from the subsurface or secondary waste streams). Because it can be difficult to compare materials due to differences in experimental conditions applied in the literature, materials will be selected for subsequent standardized batch loading tests.
ArticleNumber 132820
Author Saslow, Sarah A.
Levitskaia, Tatiana G.
Szecsody, Jim E.
Freedman, Vicky L.
Pearce, Carolyn I.
Lawter, Amanda R.
Moore, Robert C.
Asmussen, Robert M.
Neeway, James J.
Thallapally, Praveen K.
Chatterjee, Sayandev
Wang, Guohui
Morad, Joseph W.
Qafoku, Nikolla P.
Rigali, Mark J.
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  givenname: Robert C.
  surname: Moore
  fullname: Moore, Robert C.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 2
  givenname: Carolyn I.
  orcidid: 0000-0003-3098-1615
  surname: Pearce
  fullname: Pearce, Carolyn I.
  email: carolyn.pearce@pnnl.gov
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 3
  givenname: Joseph W.
  surname: Morad
  fullname: Morad, Joseph W.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 4
  givenname: Sayandev
  orcidid: 0000-0003-2218-5635
  surname: Chatterjee
  fullname: Chatterjee, Sayandev
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
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  surname: Levitskaia
  fullname: Levitskaia, Tatiana G.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
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  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
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  surname: Lawter
  fullname: Lawter, Amanda R.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 8
  givenname: James J.
  surname: Neeway
  fullname: Neeway, James J.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 9
  givenname: Nikolla P.
  surname: Qafoku
  fullname: Qafoku, Nikolla P.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 10
  givenname: Mark J.
  surname: Rigali
  fullname: Rigali, Mark J.
  organization: Sandia National Laboratories, Albuquerque, NM, United States of America
– sequence: 11
  givenname: Sarah A.
  surname: Saslow
  fullname: Saslow, Sarah A.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 12
  givenname: Jim E.
  surname: Szecsody
  fullname: Szecsody, Jim E.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 13
  givenname: Praveen K.
  surname: Thallapally
  fullname: Thallapally, Praveen K.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 14
  givenname: Guohui
  surname: Wang
  fullname: Wang, Guohui
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
– sequence: 15
  givenname: Vicky L.
  surname: Freedman
  fullname: Freedman, Vicky L.
  organization: Pacific Northwest National Laboratory, Richland, WA, United States of America
BackLink https://www.ncbi.nlm.nih.gov/pubmed/31982189$$D View this record in MEDLINE/PubMed
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IsDoiOpenAccess false
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Keywords Bismuth-based materials
Metal organic frameworks
Sorbents
Subsurface contamination
Hydroxyapatite
Iron oxides
Iodine
Layered double hydroxides
Language English
License Copyright © 2020 Elsevier B.V. All rights reserved.
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PublicationTitle The Science of the total environment
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Snippet Radioiodine-129 (129I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to...
Radioiodine-129 ( I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to compile...
Radioiodine-129 (¹²⁹I) in the subsurface is mobile and limited information is available on treatment technologies. Scientific literature was reviewed to...
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SubjectTerms activated carbon
aerogels
Bismuth-based materials
coordination polymers
environmental impact
hydroxides
Hydroxyapatite
Iodine
ion exchange resins
iron
Iron oxides
Layered double hydroxides
Metal organic frameworks
minerals
radionuclides
solubility
Sorbents
sorption
Subsurface contamination
Title Iodine immobilization by materials through sorption and redox-driven processes: A literature review
URI https://dx.doi.org/10.1016/j.scitotenv.2019.06.166
https://www.ncbi.nlm.nih.gov/pubmed/31982189
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