Charge density in crystalline citrinin from X-ray diffraction at 19 K

Roversi, Pietro; Merati, F.; Destro, Riccardo; Barzaghi, Mario

doi:10.1139/v96-129

Cited by 81 publications

(66 citation statements)

References 39 publications

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“…Finally, the 18 CÀH bond lengths in the methyl groups, ranging from 1.041(18) to 1.124 (14) ä, are comparable with the neutron average value of 1.059(30) ä. In this connection, it was noted [29] that when only very low temperature neutron measurements are considered, larger methyl CÀH distances are usually observed, approaching our average value.…”

Section: Resultssupporting

confidence: 83%

“…The existence of a correlation between 1 b values and bond lengths has been extensively investigated. [29,37,38] Generally, both experimental and theoretical data fit a simple linear model, 1 b = aR AB + b, very well, giving similar slopes and only slightly different intercepts depending on the method used to obtain the data. To reduce the systematic differences due to the methodological approach (experimental apparatus, data treatment, etc.…”

Section: à30mentioning

confidence: 97%

“…To reduce the systematic differences due to the methodological approach (experimental apparatus, data treatment, etc. ), the properties of the CC bonds of PPE were compared with those of two organic molecules analyzed in our laboratory at T < 25 K, namely citrinin [29] and syn-1,6:8,13-bis-carbonyl [14]annulene (BCA).…”

Section: à30mentioning

confidence: 99%

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Electron Density Investigation of a Push–Pull Ethylene (C₁₄H₂₄N₂O₂⋅H₂O) by X‐ray Diffraction atT= 21 K

Forni¹,

Destro²

2003

Chemistry A European J

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The electron charge distribution in a strongly twisted push-pull ethylene [PPE, 3-(1,3-diisopropyl-2-imidazolidinylidene)-2,4-pentanedione] has been determined by low temperature (T = 21 K) single-crystal X-ray diffraction analysis. The derived electronic properties are consistent with a zwitterionic molecule, as indicated by a charge transfer of 0.82(16) e from the push to the pull moieties and a charge polarization of 0.29(7) e on the olefinic bond. A dipole moment of 12(3) D has been determined, which compares well with ab initio theoretical results in terms of both modulus and orientation. The second moments, which have also been obtained with good precision, characterize PPE as a highly quadrupolar molecule. The special electronic features of the molecule confer particular topological properties to the electron density distribution, as evidenced by comparison with "standard" organic molecules. The crystallographic asymmetric unit of the present system includes one water molecule, which is hydrogen bonded to PPE. Its topological properties have also been investigated, together with an analysis of the hydrogen bonds involved.

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Section: Resultssupporting

confidence: 83%

Section: à30mentioning

confidence: 97%

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Electron Density Investigation of a Push–Pull Ethylene (C₁₄H₂₄N₂O₂⋅H₂O) by X‐ray Diffraction atT= 21 K

Forni¹,

Destro²

2003

Chemistry A European J

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“…Structurefactor phases, which cannot be measured, are treated as Non-uniform prior-prejudice distribution UP Uniform prior-prejudice distribution NNM Non-nuclear density maximum ² Similar evidence of the inability of single-exponential deformation functions to account for all the information present in the observations have also been found in studies of organic (Howard et al, 1995;Roversi, Barzaghi, Merati & Destro, 1996) and inorganic (Souhassou et al, 1995) molecular crystals. constants at each cycle of re®nement and assumed equal to the calculated values at the previous cycle, but do undergo changes from one cycle to the next. This problem has recently been brought to general attention in the context of re®nement of macromolecular structures, where inappropriate treatment of phases can result in a signi®cant source of variance being absent from the least-squares variance±covariance matrix and in phase bias being locked in by the use of an incomplete model .…”

Section: Model Bias In Conventional Charge-density Studiesmentioning

confidence: 66%

Accurate Charge-Density Studies as an Extension of Bayesian Crystal Structure Determination

Roversi¹,

Irwin²,

Bricogne³

1998

Acta Cryst Sect A

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Many hopes and much controversy have surrounded the application of the maximum-entropy (ME) method to accurate charge-density studies. This paper shows that viewing such studies as an extension of Bayesian crystal structure determination provides practical means of ful®lling many of the hopes invested in the ME method, while essentially eliminating its controversial aspects, the latter being explained in terms of a number of computational artefacts. The positional probability distribution of scatterers having maximum entropy relative to a given`prior prejudice' is computed so as to reproduce a set of phased structure-factor amplitudes; core electrons can optionally be treated as a ®xed fragment' and described using atomic core densities derived from ab initio wave functions. Fragment and prior-prejudice density distributions are computed by fast Fourier transforms and are thermally smeared by aliasing. These various algorithms have been implemented within the BUSTER computer program. Model studies on noise-free synthetic data sets for -glycine, silicon and beryllium show that all-electron calculations give rise to artefacts when a uniform prior prejudice is used, while valence-only calculations using valence monopole priors are essentially free from artefacts. The maximum-entropy approach is thus optimally implemented by incorporating the prior knowledge of the existence of sharp atomic cores in the form of a fragment not subjected to entropy maximization. These results contribute to settling the debate about the putative existence of non-nuclear density maxima at special positions for crystalline silicon and beryllium, and prepare the ground for developing maximumlikelihood multipolar re®nement.

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“…This de®nition is ®rmly based on quantum-mechanical methods. Recently, the QTAM has been successfully applied to experimentally determined electron densities derived from X-ray singlecrystal diffraction data (Flensburg et al, 1995;Howard et al, 1995;Bianchi et al, 1996;Espinosa et al, 1996;Roversi et al, 1996;Koritsa Â nszky et al, 1998;Madsen, Flensburg & Larsen, 1998;Madsen, Iversen et al, 1998). These analyses have been based on the location and characterization of critical points [r&r c 0] for intramolecular and hydrogen-bond interactions in the electron density.…”

Section: Introductionmentioning

confidence: 99%

Atoms in crystals – from experimental charge densities

Flensburg

Madsen

2000

Acta Cryst Sect A

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An implementation is described of R. F. W. Bader's [Atoms in Molecules: a Quantum Theory (1990). Oxford: Clarendon Press] virial fragmentation of the electron density as applied to experimentally determined electron densities. It is analogous to the PROMEGA method [Keith (1993), PhD thesis, McMaster University, Ontario, Canada]. Integrated atomic properties have been determined using the models from two recent accurate charge‐density studies: methylammonium hydrogen succinate monohydrate and methylammonium hydrogen maleate.

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Charge density in crystalline citrinin from X-ray diffraction at 19 K

Cited by 81 publications

References 39 publications

Electron Density Investigation of a Push–Pull Ethylene (C₁₄H₂₄N₂O₂⋅H₂O) by X‐ray Diffraction atT= 21 K

Electron Density Investigation of a Push–Pull Ethylene (C₁₄H₂₄N₂O₂⋅H₂O) by X‐ray Diffraction atT= 21 K

Accurate Charge-Density Studies as an Extension of Bayesian Crystal Structure Determination

Atoms in crystals – from experimental charge densities

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Charge density in crystalline citrinin from X-ray diffraction at 19 K

Cited by 81 publications

References 39 publications

Electron Density Investigation of a Push–Pull Ethylene (C14H24N2O2⋅H2O) by X‐ray Diffraction atT= 21 K

Electron Density Investigation of a Push–Pull Ethylene (C14H24N2O2⋅H2O) by X‐ray Diffraction atT= 21 K

Accurate Charge-Density Studies as an Extension of Bayesian Crystal Structure Determination

Atoms in crystals – from experimental charge densities

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Electron Density Investigation of a Push–Pull Ethylene (C₁₄H₂₄N₂O₂⋅H₂O) by X‐ray Diffraction atT= 21 K

Electron Density Investigation of a Push–Pull Ethylene (C₁₄H₂₄N₂O₂⋅H₂O) by X‐ray Diffraction atT= 21 K