Pore‐forming process in dehydration of metakaolin‐based geopolymer

Pore‐forming process in dehydration of metakaolin‐based geopolymer

Abstract The geopolymer catalyst supports utilized in the nuclear waste containers for the Fukushima Daiichi Nuclear Power Station will be required to have high porosity and durability. This work presents the synthesis of a potassium and metakaolin‐based geopolymer and its performance upon dehydrati...

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Main Authors: Yaru Yang, Thi‐Chau‐Duyen Le, Isamu Kudo, Thi‐Mai‐Dung Do, Koichi Niihara, Hisayuki Suematsu, Gordon Thorogood
Format: Article
Language:English
Published: Wiley 2021-09-01
Series:International Journal of Ceramic Engineering & Science
Subjects:
catalyst supports
dehydration
geopolymers
pores
radioactive waste
Online Access:https://doi.org/10.1002/ces2.10100
id doaj-76ebbc9bec7e48e79b2ad77a7b479a06
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spelling doaj-76ebbc9bec7e48e79b2ad77a7b479a062021-09-24T17:13:28ZengWileyInternational Journal of Ceramic Engineering & Science2578-32702021-09-013521121610.1002/ces2.10100Pore‐forming process in dehydration of metakaolin‐based geopolymerYaru Yang0Thi‐Chau‐Duyen Le1Isamu Kudo2Thi‐Mai‐Dung Do3Koichi Niihara4Hisayuki Suematsu5Gordon Thorogood6Extreme Energy‐Density Research Institute Nagaoka University of Technology Nagaoka JapanExtreme Energy‐Density Research Institute Nagaoka University of Technology Nagaoka JapanDepartment of Nuclear System Safety Engineering Nagaoka University of Technology Nagaoka JapanExtreme Energy‐Density Research Institute Nagaoka University of Technology Nagaoka JapanExtreme Energy‐Density Research Institute Nagaoka University of Technology Nagaoka JapanExtreme Energy‐Density Research Institute Nagaoka University of Technology Nagaoka JapanExtreme Energy‐Density Research Institute Nagaoka University of Technology Nagaoka JapanAbstract The geopolymer catalyst supports utilized in the nuclear waste containers for the Fukushima Daiichi Nuclear Power Station will be required to have high porosity and durability. This work presents the synthesis of a potassium and metakaolin‐based geopolymer and its performance upon dehydration. During water content measurements of the samples, it was seen that in the demolded samples, the water content quickly decreased to less than 30% within 7 days, while the samples that had the cap removed from the container retained more than 50% of the water after 28 days. The pore size distribution of the samples that were post‐cured at different temperatures up to 28 days did not vary greatly with respect to the average pore size. We can infer that structurally stable pores were formed in the first 4 days and were not affected by the post‐curing rate, which may be related to rheological properties and the drainage path of water or hydrogen gas during post‐curing.https://doi.org/10.1002/ces2.10100catalyst supportsdehydrationgeopolymersporesradioactive waste
collection DOAJ
language English
format Article
sources DOAJ
author Yaru Yang
Thi‐Chau‐Duyen Le
Isamu Kudo
Thi‐Mai‐Dung Do
Koichi Niihara
Hisayuki Suematsu
Gordon Thorogood
spellingShingle Yaru Yang
Thi‐Chau‐Duyen Le
Isamu Kudo
Thi‐Mai‐Dung Do
Koichi Niihara
Hisayuki Suematsu
Gordon Thorogood
Pore‐forming process in dehydration of metakaolin‐based geopolymer
International Journal of Ceramic Engineering & Science
catalyst supports
dehydration
geopolymers
pores
radioactive waste
author_facet Yaru Yang
Thi‐Chau‐Duyen Le
Isamu Kudo
Thi‐Mai‐Dung Do
Koichi Niihara
Hisayuki Suematsu
Gordon Thorogood
author_sort Yaru Yang
title Pore‐forming process in dehydration of metakaolin‐based geopolymer
title_short Pore‐forming process in dehydration of metakaolin‐based geopolymer
title_full Pore‐forming process in dehydration of metakaolin‐based geopolymer
title_fullStr Pore‐forming process in dehydration of metakaolin‐based geopolymer
title_full_unstemmed Pore‐forming process in dehydration of metakaolin‐based geopolymer
title_sort pore‐forming process in dehydration of metakaolin‐based geopolymer
publisher Wiley
series International Journal of Ceramic Engineering & Science
issn 2578-3270
publishDate 2021-09-01
description Abstract The geopolymer catalyst supports utilized in the nuclear waste containers for the Fukushima Daiichi Nuclear Power Station will be required to have high porosity and durability. This work presents the synthesis of a potassium and metakaolin‐based geopolymer and its performance upon dehydration. During water content measurements of the samples, it was seen that in the demolded samples, the water content quickly decreased to less than 30% within 7 days, while the samples that had the cap removed from the container retained more than 50% of the water after 28 days. The pore size distribution of the samples that were post‐cured at different temperatures up to 28 days did not vary greatly with respect to the average pore size. We can infer that structurally stable pores were formed in the first 4 days and were not affected by the post‐curing rate, which may be related to rheological properties and the drainage path of water or hydrogen gas during post‐curing.
topic catalyst supports
dehydration
geopolymers
pores
radioactive waste
url https://doi.org/10.1002/ces2.10100
work_keys_str_mv AT yaruyang poreformingprocessindehydrationofmetakaolinbasedgeopolymer
AT thichauduyenle poreformingprocessindehydrationofmetakaolinbasedgeopolymer
AT isamukudo poreformingprocessindehydrationofmetakaolinbasedgeopolymer
AT thimaidungdo poreformingprocessindehydrationofmetakaolinbasedgeopolymer
AT koichiniihara poreformingprocessindehydrationofmetakaolinbasedgeopolymer
AT hisayukisuematsu poreformingprocessindehydrationofmetakaolinbasedgeopolymer
AT gordonthorogood poreformingprocessindehydrationofmetakaolinbasedgeopolymer
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