Hydrolytic stability in hemilabile metal–organic frameworks

McHugh, Lauren N.; McPherson, Matthew; McCormick, Laura J.; Morris, Samuel A.; Wheatley, Paul S.; Teat, Simon J.; McKay, David; Dawson, Daniel M.; F., Charlotte E.; Ashbrook, Sharon E.; Stone, Corinne A.; Smith, Martin W.; Morris, Russell E.

doi:10.1038/s41557-018-0104-x

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Hydrolytic stability in hemilabile metal–organic frameworks

Lauren N. McHugh, Matthew McPherson

, Laura J. McCormick, Samuel A. Morris, Paul S. Wheatley, Simon J. Teat, David McKay, Daniel M. Dawson, Charlotte E. F. Sansome, Sharon E. Ashbrook, Corinne A. Stone, Martin W. Smith, Russell E. Morris

Nature Chemistry, Volume: 10, Issue: 11, Pages: 1096 - 1102

Swansea University Author: Matthew McPherson

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DOI (Published version): 10.1038/s41557-018-0104-x

Abstract

Highly porous metal–organic frameworks (MOFs), which have undergone exciting developments over the past few decades, show promise for a wide range of applications. However, many studies indicate that they suffer from significant stability issues, especially with respect to their interactions with wa...

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Published in:	Nature Chemistry
ISSN:	1755-4330 1755-4349
Published:	2018
Online Access:	Check full text
URI:	https://cronfa.swan.ac.uk/Record/cronfa49833
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first_indexed	2019-04-02T10:19:32Z
last_indexed	2019-07-18T21:33:38Z
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spelling	2019-07-18T14:40:14.1313772 v2 49833 2019-04-01 Hydrolytic stability in hemilabile metal–organic frameworks 69886ed1df27345672e1a52ddee565fe 0000-0002-7529-5355 Matthew McPherson Matthew McPherson true false 2019-04-01 EEN Highly porous metal–organic frameworks (MOFs), which have undergone exciting developments over the past few decades, show promise for a wide range of applications. However, many studies indicate that they suffer from significant stability issues, especially with respect to their interactions with water, which severely limits their practical potential. Here we demonstrate how the presence of ‘sacrificial’ bonds in the coordination environment of its metal centres (referred to as hemilability) endows a dehydrated copper-based MOF with good hydrolytic stability. On exposure to water, in contrast to the indiscriminate breaking of coordination bonds that typically results in structure degradation, it is non-structural weak interactions between the MOF’s copper paddlewheel clusters that are broken and the framework recovers its as-synthesized, hydrated structure. This MOF retained its structural integrity even after contact with water for one year, whereas HKUST-1, a compositionally similar material that lacks these sacrificial bonds, loses its crystallinity in less than a day under the same conditions. Journal Article Nature Chemistry 10 11 1096 1102 1755-4330 1755-4349 13 11 2018 2018-11-13 10.1038/s41557-018-0104-x https://research-repository.st-andrews.ac.uk/handle/10023/17048 COLLEGE NANME Engineering COLLEGE CODE EEN Swansea University 2019-07-18T14:40:14.1313772 2019-04-01T11:05:40.5989151 Faculty of Science and Engineering School of Engineering and Applied Sciences - Uncategorised Lauren N. McHugh 1 Matthew McPherson 0000-0002-7529-5355 2 Laura J. McCormick 3 Samuel A. Morris 4 Paul S. Wheatley 5 Simon J. Teat 6 David McKay 7 Daniel M. Dawson 8 Charlotte E. F. Sansome 9 Sharon E. Ashbrook 10 Corinne A. Stone 11 Martin W. Smith 12 Russell E. Morris 13 0049833-10052019154156.pdf mchugh2018.pdf 2019-05-10T15:41:56.7930000 Output 10977280 application/pdf Accepted Manuscript true 2019-05-10T00:00:00.0000000 true eng
title	Hydrolytic stability in hemilabile metal–organic frameworks
spellingShingle	Hydrolytic stability in hemilabile metal–organic frameworks Matthew McPherson
title_short	Hydrolytic stability in hemilabile metal–organic frameworks
title_full	Hydrolytic stability in hemilabile metal–organic frameworks
title_fullStr	Hydrolytic stability in hemilabile metal–organic frameworks
title_full_unstemmed	Hydrolytic stability in hemilabile metal–organic frameworks
title_sort	Hydrolytic stability in hemilabile metal–organic frameworks
author_id_str_mv	69886ed1df27345672e1a52ddee565fe
author_id_fullname_str_mv	69886ed1df27345672e1a52ddee565fe_***_Matthew McPherson
author	Matthew McPherson
author2	Lauren N. McHugh Matthew McPherson Laura J. McCormick Samuel A. Morris Paul S. Wheatley Simon J. Teat David McKay Daniel M. Dawson Charlotte E. F. Sansome Sharon E. Ashbrook Corinne A. Stone Martin W. Smith Russell E. Morris
format	Journal article
container_title	Nature Chemistry
container_volume	10
container_issue	11
container_start_page	1096
publishDate	2018
institution	Swansea University
issn	1755-4330 1755-4349
doi_str_mv	10.1038/s41557-018-0104-x
college_str	Faculty of Science and Engineering
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department_str	School of Engineering and Applied Sciences - Uncategorised{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Uncategorised
url	https://research-repository.st-andrews.ac.uk/handle/10023/17048
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description	Highly porous metal–organic frameworks (MOFs), which have undergone exciting developments over the past few decades, show promise for a wide range of applications. However, many studies indicate that they suffer from significant stability issues, especially with respect to their interactions with water, which severely limits their practical potential. Here we demonstrate how the presence of ‘sacrificial’ bonds in the coordination environment of its metal centres (referred to as hemilability) endows a dehydrated copper-based MOF with good hydrolytic stability. On exposure to water, in contrast to the indiscriminate breaking of coordination bonds that typically results in structure degradation, it is non-structural weak interactions between the MOF’s copper paddlewheel clusters that are broken and the framework recovers its as-synthesized, hydrated structure. This MOF retained its structural integrity even after contact with water for one year, whereas HKUST-1, a compositionally similar material that lacks these sacrificial bonds, loses its crystallinity in less than a day under the same conditions.
published_date	2018-11-13T04:01:03Z
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Hydrolytic stability in hemilabile metal–organic frameworks

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