Controlling the crystallization of porous organic cages: Molecular Analogs of Isoreticular Frameworks Using Shape-specific Directing Solvents

Tom Hasell; Jamie L. Culshaw; Samantha Y. Chong; Marc Schmidtmann; Marc A. Little; Kim E. Jelfs; Edward O. Pyzer-Knapp; Hilary Shepherd; Dave J. Adams; Graeme M. Day; Andrew I. Cooper

doi:10.1021/ja409594s

Controlling the crystallization of porous organic cages: Molecular Analogs of Isoreticular Frameworks Using Shape-specific Directing Solvents

Tom Hasell^*, Jamie L. Culshaw, Samantha Y. Chong, Marc Schmidtmann, Marc A. Little, Kim E. Jelfs, Edward O. Pyzer-Knapp, Hilary Shepherd, Dave J. Adams, Graeme M. Day, Andrew I. Cooper

^*Corresponding author for this work

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

133 Citations (Scopus)

Abstract

Small structural changes in organic molecules can have a large influence on solid-state crystal packing, and this often thwarts attempts to produce isostructural series of crystalline solids. For metal-organic frameworks and covalent organic frameworks, this has been addressed by using strong, directional intermolecular bonding to create families of isoreticular solids. Here, we show that an organic directing solvent, 1,4-dioxane, has a dominant effect on the lattice energy for a series of organic cage molecules. Inclusion of dioxane directs the crystal packing for these cages away from their lowest-energy polymorphs to form isostructural, 3-dimensional diamondoid pore channels. This is a unique function of the size, chemical function, and geometry of 1,4-dioxane, and hence, a noncovalent auxiliary interaction assumes the role of directional coordination bonding or covalent bonding in extended crystalline frameworks. For a new cage, CC13, a dual, interpenetrating pore structure is formed that doubles the gas uptake and the surface area in the resulting dioxane-directed crystals.

Original language	English
Pages (from-to)	1438-1448
Number of pages	11
Journal	Journal of the American Chemical Society
Volume	136
Issue number	4
DOIs	https://doi.org/10.1021/ja409594s
Publication status	Published - 29 Jan 2014

ASJC Scopus subject areas

Catalysis
General Chemistry
Biochemistry
Colloid and Surface Chemistry

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Hasell, T., Culshaw, J. L., Chong, S. Y., Schmidtmann, M., Little, M. A., Jelfs, K. E., Pyzer-Knapp, E. O., Shepherd, H., Adams, D. J., Day, G. M., & Cooper, A. I. (2014). Controlling the crystallization of porous organic cages: Molecular Analogs of Isoreticular Frameworks Using Shape-specific Directing Solvents. Journal of the American Chemical Society, 136(4), 1438-1448. https://doi.org/10.1021/ja409594s

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title = "Controlling the crystallization of porous organic cages: Molecular Analogs of Isoreticular Frameworks Using Shape-specific Directing Solvents",

abstract = "Small structural changes in organic molecules can have a large influence on solid-state crystal packing, and this often thwarts attempts to produce isostructural series of crystalline solids. For metal-organic frameworks and covalent organic frameworks, this has been addressed by using strong, directional intermolecular bonding to create families of isoreticular solids. Here, we show that an organic directing solvent, 1,4-dioxane, has a dominant effect on the lattice energy for a series of organic cage molecules. Inclusion of dioxane directs the crystal packing for these cages away from their lowest-energy polymorphs to form isostructural, 3-dimensional diamondoid pore channels. This is a unique function of the size, chemical function, and geometry of 1,4-dioxane, and hence, a noncovalent auxiliary interaction assumes the role of directional coordination bonding or covalent bonding in extended crystalline frameworks. For a new cage, CC13, a dual, interpenetrating pore structure is formed that doubles the gas uptake and the surface area in the resulting dioxane-directed crystals.",

author = "Tom Hasell and Culshaw, {Jamie L.} and Chong, {Samantha Y.} and Marc Schmidtmann and Little, {Marc A.} and Jelfs, {Kim E.} and Pyzer-Knapp, {Edward O.} and Hilary Shepherd and Adams, {Dave J.} and Day, {Graeme M.} and Cooper, {Andrew I.}",

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Hasell, T, Culshaw, JL, Chong, SY, Schmidtmann, M, Little, MA, Jelfs, KE, Pyzer-Knapp, EO, Shepherd, H, Adams, DJ, Day, GM & Cooper, AI 2014, 'Controlling the crystallization of porous organic cages: Molecular Analogs of Isoreticular Frameworks Using Shape-specific Directing Solvents', Journal of the American Chemical Society, vol. 136, no. 4, pp. 1438-1448. https://doi.org/10.1021/ja409594s

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AU - Schmidtmann, Marc

AU - Little, Marc A.

AU - Jelfs, Kim E.

AU - Pyzer-Knapp, Edward O.

AU - Shepherd, Hilary

AU - Adams, Dave J.

AU - Day, Graeme M.

AU - Cooper, Andrew I.

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N2 - Small structural changes in organic molecules can have a large influence on solid-state crystal packing, and this often thwarts attempts to produce isostructural series of crystalline solids. For metal-organic frameworks and covalent organic frameworks, this has been addressed by using strong, directional intermolecular bonding to create families of isoreticular solids. Here, we show that an organic directing solvent, 1,4-dioxane, has a dominant effect on the lattice energy for a series of organic cage molecules. Inclusion of dioxane directs the crystal packing for these cages away from their lowest-energy polymorphs to form isostructural, 3-dimensional diamondoid pore channels. This is a unique function of the size, chemical function, and geometry of 1,4-dioxane, and hence, a noncovalent auxiliary interaction assumes the role of directional coordination bonding or covalent bonding in extended crystalline frameworks. For a new cage, CC13, a dual, interpenetrating pore structure is formed that doubles the gas uptake and the surface area in the resulting dioxane-directed crystals.

AB - Small structural changes in organic molecules can have a large influence on solid-state crystal packing, and this often thwarts attempts to produce isostructural series of crystalline solids. For metal-organic frameworks and covalent organic frameworks, this has been addressed by using strong, directional intermolecular bonding to create families of isoreticular solids. Here, we show that an organic directing solvent, 1,4-dioxane, has a dominant effect on the lattice energy for a series of organic cage molecules. Inclusion of dioxane directs the crystal packing for these cages away from their lowest-energy polymorphs to form isostructural, 3-dimensional diamondoid pore channels. This is a unique function of the size, chemical function, and geometry of 1,4-dioxane, and hence, a noncovalent auxiliary interaction assumes the role of directional coordination bonding or covalent bonding in extended crystalline frameworks. For a new cage, CC13, a dual, interpenetrating pore structure is formed that doubles the gas uptake and the surface area in the resulting dioxane-directed crystals.

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Controlling the crystallization of porous organic cages: Molecular Analogs of Isoreticular Frameworks Using Shape-specific Directing Solvents

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