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Experimental and theoretical investigations of the polymorphism of 5-chloroacetoxybenzoic acid (5-chloroaspirin)

Experimental and theoretical investigations of the polymorphism of 5-chloroacetoxybenzoic acid (5-chloroaspirin)
Experimental and theoretical investigations of the polymorphism of 5-chloroacetoxybenzoic acid (5-chloroaspirin)
From an initial crystallographic study of a large family of ring-substituted 2-acetoxybenzoic acids, only one member - the 5-chloro derivative - showed polymorphism, with two forms (alpha and beta) identified, the former having a marginally higher melting point. The two structures show a close 1-D similarity through a row of carboxylic dimers connected via Cl center dot center dot center dot O halogen bonds, which assemble to give an approximate 2-D similarity by the stacking of these rows in a second direction. However, the further packing arrangement of the resulting 2-D stacks is significantly different in the two forms, through different symmetry arrangements and subtle variations in C-H center dot center dot center dot O weak hydrogen bonds. A parallel crystal structure prediction (CSP) calculation identified the two experimental polymorphs in the correct stability order with effective energy rankings of 2 and 3 (lattice energy difference of 0.2 kcal mol(-1)). The lowest energy crystal structure found during the CSP, as yet not found experimentally, is more stable than the lowest energy observed polymorph by 0.08 kcal mol(-1). The predicted forms mostly comprise pairs of structures with nearly identical crystal structure arrangements, which differ only in the positioning of the carboxylate protons in the common carboxylate-carboxylate hydrogen-bonded dimers, relative to the positions of the neighboring acetyl substituents (syn or anti). The CSP calculations identify the correct isomer for each polymorph. One of the additional predicted forms is found to have 3-D packing similarity, and others partial similarities, with the crystal structures of particular members of the extended aspirin family.
1466-8033
1672-1680
Montis, Riccardo
11e15e46-6671-4ed0-9457-db82828bcdc7
Hursthouse, Michael B.
57a2ddf9-b1b3-4f38-bfe9-ef2f526388da
Chan, H.C. Stephen
7f3df03a-3caa-47e4-9b84-13cf03c9e250
Kendrick, John
94d1a2a2-6c7e-41f8-8ef2-036d5bdfa930
Leusen, Frank J.J.
d41462dd-3804-4380-ad6f-c45e9faeec45
Montis, Riccardo
11e15e46-6671-4ed0-9457-db82828bcdc7
Hursthouse, Michael B.
57a2ddf9-b1b3-4f38-bfe9-ef2f526388da
Chan, H.C. Stephen
7f3df03a-3caa-47e4-9b84-13cf03c9e250
Kendrick, John
94d1a2a2-6c7e-41f8-8ef2-036d5bdfa930
Leusen, Frank J.J.
d41462dd-3804-4380-ad6f-c45e9faeec45

Montis, Riccardo, Hursthouse, Michael B., Chan, H.C. Stephen, Kendrick, John and Leusen, Frank J.J. (2012) Experimental and theoretical investigations of the polymorphism of 5-chloroacetoxybenzoic acid (5-chloroaspirin). CrystEngComm, 14 (5), 1672-1680. (doi:10.1039/c2ce06313a).

Record type: Article

Abstract

From an initial crystallographic study of a large family of ring-substituted 2-acetoxybenzoic acids, only one member - the 5-chloro derivative - showed polymorphism, with two forms (alpha and beta) identified, the former having a marginally higher melting point. The two structures show a close 1-D similarity through a row of carboxylic dimers connected via Cl center dot center dot center dot O halogen bonds, which assemble to give an approximate 2-D similarity by the stacking of these rows in a second direction. However, the further packing arrangement of the resulting 2-D stacks is significantly different in the two forms, through different symmetry arrangements and subtle variations in C-H center dot center dot center dot O weak hydrogen bonds. A parallel crystal structure prediction (CSP) calculation identified the two experimental polymorphs in the correct stability order with effective energy rankings of 2 and 3 (lattice energy difference of 0.2 kcal mol(-1)). The lowest energy crystal structure found during the CSP, as yet not found experimentally, is more stable than the lowest energy observed polymorph by 0.08 kcal mol(-1). The predicted forms mostly comprise pairs of structures with nearly identical crystal structure arrangements, which differ only in the positioning of the carboxylate protons in the common carboxylate-carboxylate hydrogen-bonded dimers, relative to the positions of the neighboring acetyl substituents (syn or anti). The CSP calculations identify the correct isomer for each polymorph. One of the additional predicted forms is found to have 3-D packing similarity, and others partial similarities, with the crystal structures of particular members of the extended aspirin family.

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e-pub ahead of print date: 20 December 2011
Published date: 2012
Organisations: Organic Chemistry: Synthesis, Catalysis and Flow

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Local EPrints ID: 347315
URI: http://eprints.soton.ac.uk/id/eprint/347315
ISSN: 1466-8033
PURE UUID: dd9cbe98-beb0-4587-89f7-d03948e1d444

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Date deposited: 21 Jan 2013 10:09
Last modified: 14 Mar 2024 12:46

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Contributors

Author: Riccardo Montis
Author: H.C. Stephen Chan
Author: John Kendrick
Author: Frank J.J. Leusen

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