A quantum crystallographic approach to short hydrogen bonds
A quantum crystallographic approach to short hydrogen bonds
In this work we use high-resolution synchrotron X-ray diffraction for electron density mapping, in conjunction withab initiomodelling, to study short O—H⋯O and O+—H⋯O−hydrogen bonds whose behaviour is known to be tuneable by temperature. The short hydrogen bonds have donor-acceptor distances in the region of 2.45 Å and are formed in substituted urea and organic acid molecular complexes ofN,N′-dimethylurea oxalic acid 2 : 1 (1),N,N-dimethylurea 2,4-dinitrobenzoate 1 : 1 (2) andN,N-dimethylurea 3,5-dinitrobenzoic acid 2 : 2 (3). From the combined analyses, these complexes are found to fall within the salt-cocrystal continuum and exhibit short hydrogen bonds that can be characterised as both strong and electrostatic (1,3) or very strong with a significant covalent contribution (2). An additional charge assisted component is found to be important in distinguishing the relatively uncommon O—H⋯O pseudo-covalent interaction from a typical strong hydrogen bond. The electron density is found to be sensitive to the extent of static proton transfer, presenting it as a useful parameter in the study of the salt-cocrystal continuum. From complementary calculated hydrogen atom potentials, we attribute changes in proton position to the molecular environment. Calculated potentials also show zero barrier to proton migration, forming an ‘energy slide’ between the donor and acceptor atoms. The better fundamental understanding of the short hydrogen bond in the ‘zone of fluctuation’ presented in a salt-cocrystal continuum, enabled by studies like this, provide greater insight into their related properties and can have implications in the regulation of pharmaceutical materials.
6180-6190
Saunders, Lucy K.
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Pallipurath, Anuradha R.
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Gutmann, Matthias J.
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Nowell, Harriott
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Zhang, Ningjin
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Allan, David R.
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30 September 2021
Saunders, Lucy K.
3bcb94b3-9600-4926-817f-812992f804d8
Pallipurath, Anuradha R.
d63253db-11c5-406e-99b3-a7488c276a01
Gutmann, Matthias J.
fdb6cec1-0be5-426a-a0e3-7a2e99fd0392
Nowell, Harriott
987fadc9-e0a4-477b-bfdb-420d47690cdd
Zhang, Ningjin
96cb5378-d12f-4ecb-84cf-6be24322956a
Allan, David R.
311ec351-bbfd-4e05-bfd4-c571b7cb5f21
Saunders, Lucy K., Pallipurath, Anuradha R., Gutmann, Matthias J., Nowell, Harriott, Zhang, Ningjin and Allan, David R.
(2021)
A quantum crystallographic approach to short hydrogen bonds.
CrystEngComm, 23 (35), .
(doi:10.1039/d1ce00355k).
Abstract
In this work we use high-resolution synchrotron X-ray diffraction for electron density mapping, in conjunction withab initiomodelling, to study short O—H⋯O and O+—H⋯O−hydrogen bonds whose behaviour is known to be tuneable by temperature. The short hydrogen bonds have donor-acceptor distances in the region of 2.45 Å and are formed in substituted urea and organic acid molecular complexes ofN,N′-dimethylurea oxalic acid 2 : 1 (1),N,N-dimethylurea 2,4-dinitrobenzoate 1 : 1 (2) andN,N-dimethylurea 3,5-dinitrobenzoic acid 2 : 2 (3). From the combined analyses, these complexes are found to fall within the salt-cocrystal continuum and exhibit short hydrogen bonds that can be characterised as both strong and electrostatic (1,3) or very strong with a significant covalent contribution (2). An additional charge assisted component is found to be important in distinguishing the relatively uncommon O—H⋯O pseudo-covalent interaction from a typical strong hydrogen bond. The electron density is found to be sensitive to the extent of static proton transfer, presenting it as a useful parameter in the study of the salt-cocrystal continuum. From complementary calculated hydrogen atom potentials, we attribute changes in proton position to the molecular environment. Calculated potentials also show zero barrier to proton migration, forming an ‘energy slide’ between the donor and acceptor atoms. The better fundamental understanding of the short hydrogen bond in the ‘zone of fluctuation’ presented in a salt-cocrystal continuum, enabled by studies like this, provide greater insight into their related properties and can have implications in the regulation of pharmaceutical materials.
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d1ce00355k
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Accepted/In Press date: 27 July 2021
e-pub ahead of print date: 13 August 2021
Published date: 30 September 2021
Additional Information:
Funding Information:
We thank Florian Kleemiss and Horst Puschmann from the HAR/Olex2 team for useful discussions on running the NoSphereA2 refinement software. We thank Emil Darmsgaard and Lennard Krause of the Overgaard Group at Aarhus University for sharing practical knowledge on performing charge density refinements in XD2006. We thank Diamond Light Source, funded by the Wellcome Trust and the Science and Technology Facilities Council, for access to beamline I19-189 (NR18193) for data for samples 1–3. We thank the ISIS Pulsed Neutron and Muon Source, funded by UKRI and the Science and Technology Facilities Council, for access to beamline SXD90 for data on sample 2. The computational work was undertaken on ARC3, part of the high performance computing facilities at the University of Leeds, UK. ARP acknowledges the financial support from the Future Continuous Manufacturing and Advanced Crystallization (CMAC) Hub (EPSRC Grant EP/P006965/1). The authors also thank Prof Sven Schroeder and Dr Jonathan Skelton for fruitful discussions about the potential energy surface calculations.
Publisher Copyright:
© The Royal Society of Chemistry 2021.
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
Identifiers
Local EPrints ID: 453636
URI: http://eprints.soton.ac.uk/id/eprint/453636
ISSN: 1466-8033
PURE UUID: b63b0c36-c328-451a-95bd-f141403c5db8
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Date deposited: 20 Jan 2022 17:41
Last modified: 17 Mar 2024 12:50
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Contributors
Author:
Lucy K. Saunders
Author:
Anuradha R. Pallipurath
Author:
Matthias J. Gutmann
Author:
Harriott Nowell
Author:
Ningjin Zhang
Author:
David R. Allan
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