Crystal Indentation Hardness

Armstrong, Ronald W.; Walley, S. M.; Elban, W. L.

doi:10.3390/cryst7010021

Cited by 7 publications

(6 citation statements)

References 41 publications

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“…Compression leads to the compaction of the API's crystal structure due to conformational and orientational changes. 27 The influence of pressure on a crystal structure can be studied by experimental methods such as the nanoindentation method (anisotropic compression) 28 or the method of isotropic compression in a diamond anvil cell (DAC). 29,30 Quantum chemical calculations are commonly used to explain or predict the results of experimental methods.…”

Section: Introductionmentioning

confidence: 99%

Is it possible to predict the stability of a crystal structure under the influence of pressure? Quantum chemical study of ibuprofen crystals

2022

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Section: Introductionmentioning

confidence: 99%

Is it possible to predict the stability of a crystal structure under the influence of pressure? Quantum chemical study of ibuprofen crystals

2022

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“…Mechanical properties of molecular crystals are studied by both experimental and theoretical methods. The nanoindentation method and the diamond anvil cell technique , are the most used experimental methods. Each of them has its own merits and shortcomings, but both experimental methods require special expensive equipment.…”

Section: Introductionmentioning

confidence: 99%

Quantum Chemical Modeling of Mechanical Properties of Aspirin Polymorphic Modifications

Vaksler

Idriss

Urzhuntseva

et al. 2021

Crystal Growth & Design

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Being well studied, I and II polymorphic structures of aspirin are very suitable for testing a new method to study mechanical properties using quantum chemical calculations. The proposed method consists of two steps: analysis of the pairwise interaction energies between molecules in a structure obtained by the X-ray diffraction study with separation of strongly bound fragments and further quantum chemical modeling of their displacement in relation to each other. Application of this method to aspirin polymorphs I and II showed that they have layered structure and the [001] crystallographic direction within the (100) plane is the most probable for a shear deformation, which correlates well with the data of the nanoindentation method. The energy barriers for the displacement in this direction were calculated as 17.1 and 14.5 kcal/mol for polymorphs I and II, respectively. It was shown that the area of strong repulsion between molecules belonging to the neighboring layers can complicate shear deformation in stable crystal forms I and II of aspirin. A similar study of the latest polymorph IV showed that this structure is not layered but columnar. The easiest shear deformations are possible for the displacement in the [010] crystallographic direction within the (100), (−101), and (001) planes. The low-energy barriers for these displacements (5.4, 8.8, and 9.5 kcal/mol, respectively) and the absence of significant repulsion along all the translation may explain the metastability of this structure. The proposed method is a good tool to predict mechanical properties.

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“…where n i is the position in the form of a number of the ith atom in the unit cell, Z i is the valence electron number of the ith atom crediting to the covalent bond, and V is the volume of the unit cell. More results on the hardness (various definitions of hardness) study of crystals can be referred to Suzuki et al [4], Armstrong et al [5], Mamun et al [6], Shkir et al [7], and Palatnikov et al [8]. Now, if we talk about the unit crystals studied in this article, then the first one is BC 2 , and by the first-principles computations, BC 2 was predicted originally from (a kind of tetragonal phase) the cubic diamond structure.…”

Section: Introductionmentioning

confidence: 99%

Study of Hardness of Superhard Crystals by Topological Indices

Zhang

Naeem

Baig

et al. 2021

Journal of Chemistry

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Topological indices give immense information about a molecular structure or chemical structure. The hardness of materials for the indentation can be defined microscopically as the total resistance and effect of chemical bonds in the respective materials. The aim of this paper is to study the hardness of some superhard B C x crystals by means of topological indices, specifically Randić index and atom-bond connectivity index.

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Crystal Indentation Hardness

Cited by 7 publications

References 41 publications

Is it possible to predict the stability of a crystal structure under the influence of pressure? Quantum chemical study of ibuprofen crystals

Is it possible to predict the stability of a crystal structure under the influence of pressure? Quantum chemical study of ibuprofen crystals

Quantum Chemical Modeling of Mechanical Properties of Aspirin Polymorphic Modifications

Study of Hardness of Superhard Crystals by Topological Indices

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