Control over catenation in metal-organic frameworks via rational design of the organic building block

Omar K. Farha; Christos D. Malliakas; Mercouri G. Kanatzidis; Joseph T. Hupp

doi:10.1021/ja909519e

Control over catenation in metal-organic frameworks via rational design of the organic building block

Omar K. Farha, Christos D. Malliakas, Mercouri G. Kanatzidis, Joseph T. Hupp

Chemistry

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

343 Scopus citations

Abstract

(Chemical Equation Presented) Metal-organic frameworks (MOFs), a hybrid class of materials comprising inorganic nodes and organic struts, have potential application in many areas due to their high surface areas and uniform pores and channels. One of the key challenges to be overcome in MOF synthesis is the strong propensity for catenation (growth of multiple independent networks within a given crystal), as catenation reduces cavity sizes and diminishes porosity. Here we demonstrate that rational design of organic building blocks, which act as strut-impervious scaffolds, can be exploited to generate highly desired noncatenated materials in a controlled fashion.

Original language	English (US)
Pages (from-to)	950-952
Number of pages	3
Journal	Journal of the American Chemical Society
Volume	132
Issue number	3
DOIs	https://doi.org/10.1021/ja909519e
State	Published - 2010

ASJC Scopus subject areas

General Chemistry
Biochemistry
Catalysis
Colloid and Surface Chemistry

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10.1021/ja909519e

Cite this

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abstract = "(Chemical Equation Presented) Metal-organic frameworks (MOFs), a hybrid class of materials comprising inorganic nodes and organic struts, have potential application in many areas due to their high surface areas and uniform pores and channels. One of the key challenges to be overcome in MOF synthesis is the strong propensity for catenation (growth of multiple independent networks within a given crystal), as catenation reduces cavity sizes and diminishes porosity. Here we demonstrate that rational design of organic building blocks, which act as strut-impervious scaffolds, can be exploited to generate highly desired noncatenated materials in a controlled fashion.",

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PY - 2010

Y1 - 2010

N2 - (Chemical Equation Presented) Metal-organic frameworks (MOFs), a hybrid class of materials comprising inorganic nodes and organic struts, have potential application in many areas due to their high surface areas and uniform pores and channels. One of the key challenges to be overcome in MOF synthesis is the strong propensity for catenation (growth of multiple independent networks within a given crystal), as catenation reduces cavity sizes and diminishes porosity. Here we demonstrate that rational design of organic building blocks, which act as strut-impervious scaffolds, can be exploited to generate highly desired noncatenated materials in a controlled fashion.

AB - (Chemical Equation Presented) Metal-organic frameworks (MOFs), a hybrid class of materials comprising inorganic nodes and organic struts, have potential application in many areas due to their high surface areas and uniform pores and channels. One of the key challenges to be overcome in MOF synthesis is the strong propensity for catenation (growth of multiple independent networks within a given crystal), as catenation reduces cavity sizes and diminishes porosity. Here we demonstrate that rational design of organic building blocks, which act as strut-impervious scaffolds, can be exploited to generate highly desired noncatenated materials in a controlled fashion.

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Control over catenation in metal-organic frameworks via rational design of the organic building block

Abstract

ASJC Scopus subject areas

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CCDC 747773: Experimental Crystal Structure Determination

CCDC 747767: Experimental Crystal Structure Determination

CCDC 747771: Experimental Crystal Structure Determination

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Control over catenation in metal-organic frameworks via rational design of the organic building block

Abstract

ASJC Scopus subject areas

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Datasets

CCDC 747773: Experimental Crystal Structure Determination

CCDC 747767: Experimental Crystal Structure Determination

CCDC 747771: Experimental Crystal Structure Determination

Cite this