Melt-quenched glasses of metal-organic frameworks

T.D. Bennett; Yuanzheng Yue; P. Li; A. Qiao; H.Z. Tao; N.G. Greaves; T. Richards; G.I. Lampronti; S.A.T. Redfern; F. Blanc; O.K. Farha; J.T.  Hupp; A.K. Cheetham; D.A. Keen

doi:10.1021/jacs.5b13220

Melt-quenched glasses of metal-organic frameworks

T.D. Bennett, Yuanzheng Yue, P. Li, A. Qiao, H.Z. Tao, N.G. Greaves, T. Richards, G.I. Lampronti, S.A.T. Redfern, F. Blanc , O.K. Farha, J.T. Hupp, A.K. Cheetham , D.A. Keen

Institut for Kemi og Biovidenskab

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

234 Citationer (Scopus)

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Abstract

Crystalline solids dominate the field of metal−organic frameworks (MOFs), with access to the liquid and glass states of matter usually
prohibited by relatively low temperatures of thermal decomposition. In this work, we give due consideration to framework chemistry and topology to expand the phenomenon of the melting of 3D MOFs, linking crystal chemistry to framework melting temperature and kinetic fragility of the glass-forming liquids. Here we show that melting temperatures can be lowered by altering the chemistry of the crystalline MOF state, which provides a route to facilitate the melting of other MOFs. The glasses formed upon vitrification are chemically and structurally distinct from the three other existing categories of melt-quenched glasses (inorganic nonmetallic, organic, and metallic), and retain the basic metal−ligand connectivity of crystalline MOFs, which connects their mechanical properties to their
starting chemical composition. The transfer of functionality from crystal to glass points toward new routes to tunable, functional hybrid glasses.

Originalsprog	Engelsk
Tidsskrift	Journal of the American Chemical Society
Vol/bind	138
Udgave nummer	10
Sider (fra-til)	3484−3492
Antal sider	9
ISSN	0002-7863
DOI	https://doi.org/10.1021/jacs.5b13220
Status	Udgivet - 16 mar. 2016

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10.1021/jacs.5b13220Licens: CC BY 4.0

Open access articleForlagets udgivne version, 2,83 MBLicens: CC BY 4.0

http://pubs.acs.org.zorac.aub.aau.dk/doi/pdf/10.1021/jacs.5b13220Licens: CC BY 4.0

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AU - Bennett, T.D.

AU - Yue, Yuanzheng

AU - Li, P.

AU - Qiao, A.

AU - Tao, H.Z.

AU - Greaves, N.G.

AU - Richards, T.

AU - Lampronti, G.I.

AU - Redfern, S.A.T.

AU - Blanc , F.

AU - Farha, O.K.

AU - Hupp, J.T.

AU - Cheetham , A.K.

AU - Keen, D.A.

PY - 2016/3/16

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N2 - Crystalline solids dominate the field of metal−organic frameworks (MOFs), with access to the liquid and glass states of matter usuallyprohibited by relatively low temperatures of thermal decomposition. In this work, we give due consideration to framework chemistry and topology to expand the phenomenon of the melting of 3D MOFs, linking crystal chemistry to framework melting temperature and kinetic fragility of the glass-forming liquids. Here we show that melting temperatures can be lowered by altering the chemistry of the crystalline MOF state, which provides a route to facilitate the melting of other MOFs. The glasses formed upon vitrification are chemically and structurally distinct from the three other existing categories of melt-quenched glasses (inorganic nonmetallic, organic, and metallic), and retain the basic metal−ligand connectivity of crystalline MOFs, which connects their mechanical properties to theirstarting chemical composition. The transfer of functionality from crystal to glass points toward new routes to tunable, functional hybrid glasses.

AB - Crystalline solids dominate the field of metal−organic frameworks (MOFs), with access to the liquid and glass states of matter usuallyprohibited by relatively low temperatures of thermal decomposition. In this work, we give due consideration to framework chemistry and topology to expand the phenomenon of the melting of 3D MOFs, linking crystal chemistry to framework melting temperature and kinetic fragility of the glass-forming liquids. Here we show that melting temperatures can be lowered by altering the chemistry of the crystalline MOF state, which provides a route to facilitate the melting of other MOFs. The glasses formed upon vitrification are chemically and structurally distinct from the three other existing categories of melt-quenched glasses (inorganic nonmetallic, organic, and metallic), and retain the basic metal−ligand connectivity of crystalline MOFs, which connects their mechanical properties to theirstarting chemical composition. The transfer of functionality from crystal to glass points toward new routes to tunable, functional hybrid glasses.

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DO - 10.1021/jacs.5b13220

M3 - Journal article

SN - 0002-7863

VL - 138

SP - 3484−3492

JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

IS - 10

ER -

Melt-quenched glasses of metal-organic frameworks

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