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Why are S–F and S–O non-covalent interactions stabilising?
Karl J. Thorley, Iain McCulloch
Chemistry
Physical Sciences and Engineering
Research output
:
Contribution to journal
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Article
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peer-review
55
Scopus citations
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Keyphrases
Noncovalent Interactions
100%
Optoelectronic Materials
50%
Functional Groups
50%
Polymer Chain
50%
Dipole
50%
Material Design
50%
Interaction Types
50%
Sulfur
50%
Computational Analysis
50%
Electrostatic Interaction
50%
Molecular Chain
50%
Bulk Properties
50%
Conjugation Length
50%
Symmetry-adapted Perturbation Theory
50%
Heteroatom
50%
Design Rules
50%
Single Polymer Chain
50%
Natural Bond Orbitals Method
50%
Engineering
Covalent
100%
Polymer Chain
100%
Computational Analysis
50%
Design Rule
50%
Future Design
50%
Bulk Property
50%
Electrostatics
50%
Functional Group
50%
Chemistry
Polymer Chain
100%
Non-Covalent Interactions
100%
Optoelectronics
50%
k·p perturbation theory
50%
Electrostatic Interaction
50%
Heteroatom
50%
Natural Bond Orbital
50%
Material Science
Materials Property
100%
Electrostatic Interaction
100%
Materials Design
100%