Validation of missed space-group symmetry in X-ray powder diffraction structures with dispersion-corrected density functional theory

Hempler, Daniela; Schmidt, Martin; Streek, Jacco van de

doi:10.1107/s2052520617005935

Cited by 3 publications

(2 citation statements)

References 103 publications

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“…Nowadays, typical errors in single-crystal structure analyses include wrong space groups (see e.g. Baur & Kassner, 1992;Herbstein et al, 2002;Marsh & Clemente, 2007;Henling & Marsh, 2014;Hempler et al, 2017); overlooked, ignored or wrongly treated disorder; missing hydrogen atoms [e.g. Cp*CoCoCp* instead of Cp*CoH 3 CoCp* (Cp* = C 5 (CH 3 ) 5 ) (Kersten et al, 1992)]; misplaced hydrogen atoms; or wrong atom assignments, e.g.…”

Section: Introduction 1ambiguous Crystal Structure Solutionsmentioning

confidence: 99%

Ambiguous structure determination from powder data: four different structural models of 4,11-difluoroquinacridone with similar X-ray powder patterns, fit to the PDF, SSNMR and DFT-D

Schlesinger

Fitterer

Buchsbaum

et al. 2022

IUCrJ

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Four different structural models, which all fit the same X-ray powder pattern, were obtained in the structure determination of 4,11-difluoroquinacridone (C20H10N2O2F2) from unindexed X-ray powder data by a global fit. The models differ in their lattice parameters, space groups, Z, Z′, molecular packing and hydrogen bond patterns. The molecules form a criss-cross pattern in models A and B, a layer structure built from chains in model C and a criss-cross arrangement of dimers in model D. Nevertheless, all models give a good Rietveld fit to the experimental powder pattern with acceptable R-values. All molecular geometries are reliable, except for model D, which is slightly distorted. All structures are crystallochemically plausible, concerning density, hydrogen bonds, intermolecular distances etc. All models passed the checkCIF test without major problems; only in model A a missed symmetry was detected. All structures could have probably been published, although 3 of the 4 structures were wrong. The investigation, which of the four structures is actually the correct one, was challenging. Six methods were used: (1) Rietveld refinements, (2) fit of the crystal structures to the pair distribution function (PDF) including the refinement of lattice parameters and atomic coordinates, (3) evaluation of the colour, (4) lattice-energy minimizations with force fields, (5) lattice-energy minimizations by two dispersion-corrected density functional theory methods, and (6) multinuclear CPMAS solid-state NMR spectroscopy (1H, 13C, 19F) including the comparison of calculated and experimental chemical shifts. All in all, model B (perhaps with some disorder) can probably be considered to be the correct one. This work shows that a structure determination from limited-quality powder data may result in totally different structural models, which all may be correct or wrong, even if they are chemically sensible and give a good Rietveld refinement. Additionally, the work is an excellent example that the refinement of an organic crystal structure can be successfully performed by a fit to the PDF, and the combination of computed and experimental solid-state NMR chemical shifts can provide further information for the selection of the most reliable structure among several possibilities.

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Section: Introduction 1ambiguous Crystal Structure Solutionsmentioning

confidence: 99%

Ambiguous structure determination from powder data: four different structural models of 4,11-difluoroquinacridone with similar X-ray powder patterns, fit to the PDF, SSNMR and DFT-D

Schlesinger

Fitterer

Buchsbaum

et al. 2022

IUCrJ

Self Cite

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“…Although the task of determining crystal structures from powder XRD data is significantly more challenging than from single-crystal XRD data, advances over the past 20 years or so in techniques for analysis of powder XRD data − (particularly, the development of the direct-space strategy for structure solution) are such that the structural properties of organic materials of moderate complexity can now be determined from powder XRD data. In this regard, we note that there is growing interest ,− in utilizing periodic DFT calculations in conjunction with the analysis of powder XRD data, both for validation of the structural model and for enhancing the quality of the structure at different stages of the structure determination process. The capability to determine the crystal structures of organic materials directly from powder XRD data has created considerable opportunities for structural characterization of materials prepared by processes that intrinsically generate microcrystalline powders as the product phase, including those prepared by solid-state desolvation (e.g., dehydration) processes. ,,,, …”

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confidence: 99%

Elucidating the Crystal Structure of dl-Arginine by Combined Powder X-ray Diffraction Data Analysis and Periodic DFT-D Calculations

Hughes

Boughdiri

Bouakkaz

et al. 2017

Crystal Growth & Design

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2018. Elucidating the crystal structure of DL-Arginine by combined powder X-ray diffraction data analysis and periodic DFT-D calculations. AbstractAmong the 20 directly-encoded proteinogenic amino acids, arginine is one of five remaining cases for which the crystal structure of a racemic crystalline phase has not yet been reported. In this paper, the crystal structure of DL-arginine is determined by exploiting modern methods for analysis of powder X-ray diffraction data, in conjunction with periodic DFT-D calculations. The crystal structure of DL-arginine provides interesting contrasts and comparisons to that of the enantiomerically pure crystalline phase (L-arginine), which was also determined recently from powder X-ray diffraction data.

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Trust Not Verify? The Critical Need for Data Curation Standards in Materials Informatics

Hart,

Idanwekhai,

Alves

et al. 2024

Chem. Mater.

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The importance of data curation has been recognized in multiple areas of research; however, the discussion of this important issue is only beginning to emerge in materials science. In this Perspective, we highlight the benefits of using the standardized data curation protocols in materials science and discuss current gaps in accurate and reproducible data reporting using case studies drawn from high-impact materials science papers and well-known databases such as the Crystallography Open Database (COD) and the Cambridge Structural Database (CSD). We argue that both experimental and computational materials scientists need to embrace a culture of rigorous data curation as part of modern research data management. We propose a sample data curation pipeline for materials chemistry and illustrate its use by creating two new materials chemistry databases. We hope that this perspective will serve to catalyze further discussion and promote the continuous development of rigorous data curation practices within the materials science research community. We posit that adherence to best practices of data curation will promote and enhance the reliability, reproducibility, and integrity of materials research and enable the development of reliable AI and machine learning models that critically depend on the use of quality data.

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Validation of missed space-group symmetry in X-ray powder diffraction structures with dispersion-corrected density functional theory

Cited by 3 publications

References 103 publications

Ambiguous structure determination from powder data: four different structural models of 4,11-difluoroquinacridone with similar X-ray powder patterns, fit to the PDF, SSNMR and DFT-D

Ambiguous structure determination from powder data: four different structural models of 4,11-difluoroquinacridone with similar X-ray powder patterns, fit to the PDF, SSNMR and DFT-D

Elucidating the Crystal Structure of dl-Arginine by Combined Powder X-ray Diffraction Data Analysis and Periodic DFT-D Calculations

Trust Not Verify? The Critical Need for Data Curation Standards in Materials Informatics

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