Hirshfeld atom like refinement with alternative electron density partitions

Chodkiewicz, Michał Leszek; Woińska, Magdalena; Woźniak, Krzysztof

doi:10.1107/s2052252520013603

Cited by 28 publications

(51 citation statements)

References 76 publications

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“…A systematic analysis of the impact of the theoretical framework on the prediction of the structural factors has already been performed. The effect of the Hamiltonian, basis set, thermal smearing and partition models Bytheway et al, 2002b;Jayatilaka & Dittrich, 2008;Chodkiewicz et al, 2020), the inclusion of an explicit (Bytheway et al, 2002a) or an implicit (Dittrich et al, 2012) crystalline environment through the model of surrounding charges and dipoles, and the use of a multi-determinant approach (Genoni, 2017) on HAR are well documented. However, the influence of the experimental model setup on the XWR results has not been scrutinized in depth.…”

Section: Introductionmentioning

confidence: 99%

The influence of refinement strategies on the wavefunctions derived from an experiment

Landeros‐Rivera¹,

Contreras‐García²,

Dominiak³

2021

Acta Crystallogr B Struct Sci Cryst Eng Mater

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The synergy between theory and experiment found in X-ray wavefunction refinement (XWR) makes it one of the most compelling techniques available for chemical physics. The foremost benefit of XWR – obtaining wavefunctions constrained to experimental data – is at the same time its Achilles heel, because of the dependence of the results on the quality of both empirical and theoretical data. The purpose of this work is to answer the following: What is the effect of the refinement strategy and manipulation of input data on the physical properties obtained from XWR? With that in mind, cutoffs based on data resolution and F/σ(F) ratios were applied for both steps of XWR, the Hirshfeld atom refinement (HAR) and the X-ray constrained wavefunction fitting (XCW), for four selected systems: sulfur dioxide, urea, carbamazepine and oxalic acid. The effects of changing the weighting scheme or the method to transform σ(F 2) to σ(F) were also analysed. The results show that while HAR always reaches the same result, XCW is extremely sensitive to crystallographic data manipulation. This is a result of the variability of the experimental uncertainties for different resolution shells, and of not having proper standard uncertainties. Therefore, the use of distinct constraints for each resolution interval in XCW is proposed to fix this instability.

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Section: Introductionmentioning

confidence: 99%

The influence of refinement strategies on the wavefunctions derived from an experiment

Landeros‐Rivera¹,

Contreras‐García²,

Dominiak³

2021

Acta Crystallogr B Struct Sci Cryst Eng Mater

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“…For instance, if we consider only three alkyl groups in the active introduced the aspherical deformation of the atomic electron densities due to chemical bonding and, among them, the Hirshfeld atom refinement is the technique that recently emerged as the most promising. [110][111][112][113][114][115] This strategy consists in performing a quantum chemistry calculation at each step of the refinement (usually at HF or DFT level, even if post-HF methods have also been recently considered 128,129 ) to provide quantum mechanically rigorous electron distributions that are afterwards partitioned into aspherical atomic contributions through the stockholder Hirshfeld partitioning technique 130,131 . The obtained aspherical atomic densities are used to compute thermally averaged structure factor amplitudes N9 '<G' 9O that, along with the experimental ones N9 *H@ 9O, give the # statistical agreement:…”

Section: Computational Costmentioning

confidence: 99%

QM/ELMO: A Multi-Purpose Fully Quantum Mechanical Embedding Scheme Based on Extremely Localized Molecular Orbitals

2021

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The development of computationally advantageous methods for the study of large systems is a long-standing research topic in theoretical chemistry. Among these techniques, a prominent place is certainly occupied by the multi-scale embedding strategies, from the well-known QM/MM (quantum mechanics / molecular mechanics) methods to the latest and promising fully quantum mechanical approaches. In this Feature Article, we will briefly review the recently proposed QM/ELMO (quantum mechanics / extremely localized molecular orbital) scheme, namely a new multiscale embedding strategy in which the most chemically relevant region of the investigated system is treated at fully quantum chemical level, while the remaining part (namely, the environment) is described by means of transferred extremely localized molecular orbitals that remain frozen throughout the computation. Other than highlighting the theoretical bases, here we will also review the main results obtained through all the currently available variants of the novel method. In particular, we will show how the QM/ELMO embedding scheme has been successfully exploited to perform both ground and excited state calculations, reproducing the results of corresponding fully quantum mechanical computations but with a much lower computational cost. A first application to crystallography will be also discussed and we will describe how the QM/ELMO approach has been recently coupled with the Hirshfeld atom refinement technique to accurately determine the positions of hydrogen atoms from X-ray diffraction data.Given the reliability and quality of the obtained results, future applications of the current versions of the QM/ELMO embedding strategy to different types of chemical problems are to be expected in the near future. Moreover, further algorithmic improvements and methodological developments are also envisaged, such as the development of a polarizable QM/ELMO scheme accounting for the effects of the QM

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“…HAR offers full flexibility in the calculation of the molecular electron density in the context of choosing the method and basis set. This procedure is becoming an increasingly popular technique for structure refinement (Fugel et al, 2014;Woiń ska et al, 2016Woiń ska et al, , 2017Malaspina et al, 2019;Chodkiewicz et al, 2020;Kleemiss et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Relativistic Hirshfeld atom refinement of an organo-gold(I) compound

Pawlędzio

Malińska

Woińska

et al. 2021

IUCrJ

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The main goal of this study is the validation of relativistic Hirshfeld atom refinement (HAR) as implemented in Tonto for high-resolution X-ray diffraction datasets of an organo-gold(I) compound. The influence of the relativistic effects on statistical parameters, geometries and electron density properties was analyzed and compared with the influence of electron correlation and anharmonic atomic motions. Recent work in this field has indicated the importance of relativistic effects in the static electron density distribution of organo-mercury compounds. This study confirms that differences in electron density due to relativistic effects are also of significant magnitude for organo-gold compounds. Relativistic effects dominate not only the core region of the gold atom, but also influence the electron density in the valence and bonding region, which has measurable consequences for the HAR refinement model parameters. To study the effects of anharmonic motion on the electron density distribution, dynamic electron density difference maps were constructed. Unlike relativistic and electron correlation effects, the effects of anharmonic nuclear motion are mostly observed in the core area of the gold atom.

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Hirshfeld atom like refinement with alternative electron density partitions

Cited by 28 publications

References 76 publications

The influence of refinement strategies on the wavefunctions derived from an experiment

The influence of refinement strategies on the wavefunctions derived from an experiment

QM/ELMO: A Multi-Purpose Fully Quantum Mechanical Embedding Scheme Based on Extremely Localized Molecular Orbitals

Relativistic Hirshfeld atom refinement of an organo-gold(I) compound

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