Assessing potential supports for lithium amide-imide ammonia decomposition catalysts

Thomas Wood; Joshua W. Makepeace

doi:10.1021/acsaem.8b00351

Assessing potential supports for lithium amide-imide ammonia decomposition catalysts

Thomas Wood, Joshua W. Makepeace

Chemistry

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

Lithium amide-imide is an excellent ammonia decomposition catalyst, but its highly reactive nature makes the application of traditional heterogeneous catalyst methods challenging, including the use of porous supports. In this study, lithium amide-imide was tested for compatibility with various support materials (activated carbon, silicon dioxide, aluminum oxide and magnesium oxide). It was found that most of the supports were unsuitable because of their reactivity with the catalyst, especially under flowing ammonia at decomposition conditions (>400 °C and 1 bar). Magnesium oxide, however, did not react with lithium amide-imide under flowing ammonia. Ammonia decomposition experiments over these catalyst-support mixtures showed that the lithium amide-imide/magnesium oxide system gave the best performance and therefore represents an excellent and usable ammonia decomposition catalyst.

Original language	English
Pages (from-to)	2657-2663
Number of pages	7
Journal	ACS Applied Energy Materials
Volume	1
Issue number	6
Early online date	9 May 2018
DOIs	https://doi.org/10.1021/acsaem.8b00351
Publication status	Published - 25 Jun 2018

Keywords

ammonia decomposition
catalyst
supports
lithium amide
lithium imide

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abstract = "Lithium amide-imide is an excellent ammonia decomposition catalyst, but its highly reactive nature makes the application of traditional heterogeneous catalyst methods challenging, including the use of porous supports. In this study, lithium amide-imide was tested for compatibility with various support materials (activated carbon, silicon dioxide, aluminum oxide and magnesium oxide). It was found that most of the supports were unsuitable because of their reactivity with the catalyst, especially under flowing ammonia at decomposition conditions (>400 °C and 1 bar). Magnesium oxide, however, did not react with lithium amide-imide under flowing ammonia. Ammonia decomposition experiments over these catalyst-support mixtures showed that the lithium amide-imide/magnesium oxide system gave the best performance and therefore represents an excellent and usable ammonia decomposition catalyst.",

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N2 - Lithium amide-imide is an excellent ammonia decomposition catalyst, but its highly reactive nature makes the application of traditional heterogeneous catalyst methods challenging, including the use of porous supports. In this study, lithium amide-imide was tested for compatibility with various support materials (activated carbon, silicon dioxide, aluminum oxide and magnesium oxide). It was found that most of the supports were unsuitable because of their reactivity with the catalyst, especially under flowing ammonia at decomposition conditions (>400 °C and 1 bar). Magnesium oxide, however, did not react with lithium amide-imide under flowing ammonia. Ammonia decomposition experiments over these catalyst-support mixtures showed that the lithium amide-imide/magnesium oxide system gave the best performance and therefore represents an excellent and usable ammonia decomposition catalyst.

AB - Lithium amide-imide is an excellent ammonia decomposition catalyst, but its highly reactive nature makes the application of traditional heterogeneous catalyst methods challenging, including the use of porous supports. In this study, lithium amide-imide was tested for compatibility with various support materials (activated carbon, silicon dioxide, aluminum oxide and magnesium oxide). It was found that most of the supports were unsuitable because of their reactivity with the catalyst, especially under flowing ammonia at decomposition conditions (>400 °C and 1 bar). Magnesium oxide, however, did not react with lithium amide-imide under flowing ammonia. Ammonia decomposition experiments over these catalyst-support mixtures showed that the lithium amide-imide/magnesium oxide system gave the best performance and therefore represents an excellent and usable ammonia decomposition catalyst.

KW - ammonia decomposition

KW - catalyst

KW - supports

KW - lithium amide

KW - lithium imide

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DO - 10.1021/acsaem.8b00351

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JO - ACS Applied Energy Materials

JF - ACS Applied Energy Materials

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Assessing potential supports for lithium amide-imide ammonia decomposition catalysts

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Keywords

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