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dc.contributor.authorHylton, R.K.*
dc.contributor.authorTizzard, G.J.*
dc.contributor.authorThrelfall, T.L.*
dc.contributor.authorEllis, A.L.*
dc.contributor.authorColes, S.J.*
dc.contributor.authorSeaton, Colin C.*
dc.contributor.authorSchulze, E.*
dc.contributor.authorLorenz, H.*
dc.contributor.authorSeidel-Morgenstern, A.*
dc.contributor.authorStein, M.*
dc.contributor.authorPrice, S.L.*
dc.date.accessioned2016-11-02T15:23:56Z
dc.date.available2016-11-02T15:23:56Z
dc.date.issued02/09/2015
dc.identifier.citationHylton RK, Tizzard GJ, Threlfall TL et al (2015) Are the Crystal Structures of Enantiopure and Racemic Mandelic Acids Determined by Kinetics or Thermodynamics? Journal of the American Chemical Society. 137(34): 11095-11104.
dc.identifier.urihttp://hdl.handle.net/10454/10188
dc.descriptionYes
dc.description.abstractMandelic acids are prototypic chiral molecules where the sensitivity of crystallized forms (enantiopure/racemic compound/polymorphs) to both conditions and substituents provides a new insight into the factors that may allow chiral separation by crystallization. The determination of a significant number of single crystal structures allows the analysis of 13 enantiopure and 30 racemic crystal structures of 21 (F/Cl/Br/CH3/CH3O) substituted mandelic acid derivatives. There are some common phenyl packing motifs between some groups of racemic and enantiopure structures, although they show very different hydrogen-bonding motifs. The computed crystal energy landscape of 3-chloromandelic acid, which has at least two enantiopure and three racemic crystal polymorphs, reveals that there are many more possible structures, some of which are predicted to be thermodynamically more favorable as well as slightly denser than the known forms. Simulations of mandelic acid dimers in isolation, water, and toluene do not differentiate between racemic and enantiopure dimers and also suggest that the phenyl ring interactions play a major role in the crystallization mechanism. The observed crystallization behavior of mandelic acids does not correspond to any simple “crystal engineering rules” as there is a range of thermodynamically feasible structures with no distinction between the enantiopure and racemic forms. Nucleation and crystallization appear to be determined by the kinetics of crystal growth with a statistical bias, but the diversity of the mandelic acid crystallization behavior demonstrates that the factors that influence the kinetics of crystal nucleation and growth are not yet adequately understood.
dc.description.sponsorshipEPSRC, Max Planck Society for the Advancement of Sciences, UCL-MPS Impact Ph.D. Fellowship, EU COST Action
dc.language.isoen
dc.rights© 2015 The Authors. This is an Open Access article published under the Creative Commons CC-BY license (http://pubs.acs.org/page/policy/authorchoice_ccby_termsofuse.html)
dc.subjectCrystal structure prediction
dc.subjectNucleation
dc.subjectChiral resolution
dc.titleAre the Crystal Structures of Enantiopure and Racemic Mandelic Acids Determined by Kinetics or Thermodynamics?
dc.status.refereedYes
dc.date.application05/08/2015
dc.typeArticle
dc.type.versionPublished version
dc.identifier.doihttps://doi.org/10.1021/jacs.5b05938
dc.rights.licenseCC-BY
refterms.dateFOA2018-07-27T01:38:21Z
dc.openaccess.statusopenAccess


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