Critical Analysis of Non-Nuclear Electron-Density Maxima and the Maximum Entropy Method

Vries, R.Y. de; Briels, Willem J.; Feil, D.

doi:10.1103/physrevlett.77.1719

Cited by 74 publications

(64 citation statements)

References 21 publications

(32 reference statements)

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“…Since representation of disordered crystal structures by split-atom models in Rietveld analysis is far from perfect, such spherical distributions of electrons for the disordered sites are ascribable to a bias toward procrystal prior densities. Even though MEM can reconstruct peaks that do not exist in prior densities (de Vries et al, 1996), false characteristics of procrystal prior ones can hardly be erased in powder diffraction because F obs (h j )'s for overlapped reflections are estimated on the basis of the same structural model in the preceding Rietveld analysis (Rietveld, 1969).…”

Section: Sr 9 In(po 4 )mentioning

confidence: 99%

“…One of the errors is caused by a seriestermination effect arising from the availability of only a limited number of reflections (Jauch, 1994;de Vries et al, 1996;Palatinus and van Smaalen, 2002), although this effect is much less significant in MEM than in Fourier synthesis. On the analysis of X-ray diffraction data, MEM also tends to give large residual errors for some low-Q reflections that contribute most significantly to information entropy, S. Such a tendency of MEM often generates artifacts in calculated electron densities even if accurate standard uncertainties, σ(h j ), of F obs (h j )'s are obtainable (de Vries et al, 1994;Palatinus and van Smaalen, 2002).…”

Section: Introductionmentioning

confidence: 99%

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Dysnomia, a computer program for maximum-entropy method (MEM) analysis and its performance in the MEM-based pattern fitting

et al. 2013

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A computer program, Dysnomia, for the maximum-entropy method (MEM) has been tested for the evaluation and advancement of MEM-based pattern fitting (MPF). Dysnomia is a successor to PRIMA, which was the only program integrated with RIETAN-FP for MPF. Two types of MEM algorithms, i.e., 0th-order single-pixel approximation and a variant of the Cambridge algorithm, were implemented in Dysnomia in combination with a linear combination of the "generalized F constraints" and arbitrary weighting factors for them. Dysnomia excels PRIMA in computation speed, memory efficiency, and scalability owing to parallel processing and automatic switching of discrete Fourier transform and fast Fourier transform depending on sizes of grids and observed reflections. These features of Dysnomia were evaluated for MPF analyses from X-ray powder diffraction data of three different types of compounds: taurine, Cu 2 CO 3 (OH) 2 (malachite), and Sr 9 In(PO 4 ) 7 . Reliability indices in MPF analyses proved to have been improved by using multiple F constraints and weighting factors based on lattice-plane spacings, d, in comparison with those obtained with PRIMA.

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Section: Sr 9 In(po 4 )mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dysnomia, a computer program for maximum-entropy method (MEM) analysis and its performance in the MEM-based pattern fitting

et al. 2013

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“…Furthermore, the MEM has been used as an alternative method to multipole re®nements, with the purpose to compute accurate electron densities that reveal the bonding electrons. After the ®rst promising applications in this ®eld (Collins, 1982;Sakata & Sato, 1990), several warnings concerning the reliability and possible pathologies of the method appeared (Jauch, 1994;de Vries et al, 1996).…”

Section: Introductionmentioning

confidence: 99%

The maximum-entropy method in superspace

Smaalen¹,

2003

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One of the applications of the maximum-entropy method (MEM) in crystallography is the reconstruction of the electron density from phased structure factors. Here the application of the MEM to incommensurately modulated crystals and incommensurate composite crystals is considered. The MEM is computed directly in superspace, where the electron density in the (3+d)-dimensional unit cell (d > 0) is determined from the scattering data of aperiodic crystals. Periodic crystals (d = 0) are treated as a special case of the general formalism. The use of symmetry in the MEM is discussed and an ef®cient algorithm is proposed for handling crystal symmetry. The method has been implemented into a computer program BayMEM and applications are presented to the electron density of the periodic crystal NaV 2 O 5 and the electron density of the incommensurate composite crystal (LaS) 1.14 NbS 2 . The MEM in superspace is shown to provide a model-independent estimate of the shapes of the modulation functions of incommensurate crystals. The discrete character of the electron density is found to be the major source of error, limiting the accuracy of the reconstructed modulation functions to approximately 10% of the sizes of the pixels. MaxEnt optimization using the Cambridge and Sakata±Sato algorithms are compared. The Cambridge algorithm is found to perform better than the Sakata±Sato algorithm, being faster, always reaching convergence, and leading to more reliable density maps. Nevertheless, the Sakata±Sato algorithm leads to similar density maps, even in cases where it does not reach complete convergence.

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“…For comparison, the computations using the ad hoc weighting (de Vries et al, 1996, referred to as static weighting hereafter) were performed on the noisy data sets. The F constraint with additional static weighting is de®ned as…”

Section: Computational Detailsmentioning

confidence: 99%

“…In crystallography, one particular application is the investigation of the electron density in the crystal structure. After the ®rst promising applications in this ®eld (Collins, 1982;Sakata & Sato, 1990), several warnings concerning the reliability and possible pathologies of the method appeared (Jauch, 1994;de Vries et al, 1996). One of the obvious problems was that the distribution of the normalized residuals of the structure factors ÁFHa'H jF obs Hj À jF calc Hja'H strongly deviated from the expected Gaussian distribution.…”

Section: Introductionmentioning

confidence: 99%

The generalizedFconstraint in the maximum-entropy method – a study on simulated data

Palatinus

Smaalen²

2002

Acta Cryst Sect A

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One of the classical problems in the application of the maximum-entropy method (MEM) to electron-density reconstructions is the uneven distribution of the normalized residuals of the structure factors jF obs Hj À jF calc Hja'H of the resulting electron density. This distribution does not correspond to the expected Gaussian distribution and it leads to erroneous features in the MEM reconstructions. It is shown that the classical 1 2 constraint is only one of many possible constraints, and that it is too weak to restrict the resulting distribution to the expected Gaussian shape. It is proposed that constraints should be used that are based on the higher-order central moments of the distribution of the structure-factor residuals. In this work, the in¯uence of different constraints on the quality of the MEM reconstruction is investigated. It is proposed that the use of a combined constraint on more than one central moment simultaneously would lead to again improved results. Oxalic acid dihydrate was chosen as model structure, from which several data sets with different resolutions and different levels of noise were calculated and subsequently used in the MEM. The results clearly show that the use of different constraints leads to signi®cantly improved results.

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Critical Analysis of Non-Nuclear Electron-Density Maxima and the Maximum Entropy Method

Cited by 74 publications

References 21 publications

Dysnomia, a computer program for maximum-entropy method (MEM) analysis and its performance in the MEM-based pattern fitting

Dysnomia, a computer program for maximum-entropy method (MEM) analysis and its performance in the MEM-based pattern fitting

The maximum-entropy method in superspace

The generalizedFconstraint in the maximum-entropy method – a study on simulated data

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