The dynamical theory of X-ray Bragg diffraction from a crystal with a uniform strain gradient. The Green–Riemann functions

Chukhovskii, F. N.; Gabrielyan, K. T.; Petrashen, P. V.

doi:10.1107/s056773947800128x

Cited by 79 publications

(41 citation statements)

References 4 publications

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“…Models following an eikonal approximation based on rays were developed and solved for the Laue geometry, and solutions of wave equations were presented for the Laue case with a spherical incident wave (Katagawa & Kato, 1974;Chukhovskii & Petrashen', 1977). Forms of solution in Bragg reflection for thick crystals in certain limits have been developed (Chukhovskii, Gabrielyan & Petrashen', 1978;Chukhovskii, Gabrielyan, Kislovskii & Prokopenko, 1987;Chukhovskii & Malgrange, 1989) but precision calculation of profiles or extension to non-ideal crystals has not been achieved. Standard implementations for curved-crystal Johann spectroscopy of synchrotron, stationary and fast-beam sources use idealized crystal elements, neglecting centroid, width and profile effects (Beyer & Liesen, 1988;Suortti & Freund, 1989).…”

Section: Introductionmentioning

confidence: 99%

X-ray diffraction of bent crystals in Bragg geometry. I. Perfect-crystal modelling

Chantler¹

1992

J Appl Cryst

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X-ray reflectivity, widths, centroid shifts and profiles for curved perfect crystals are calculated from a model. The crystal is approximated by a stack of perfectcrystal lamellae or blocks with a gradually changing (mean) orientation. A computer program has been developed to calculate the above quantities in the Johann geometry for the composite crystal from the dynamic theory of diffraction. Focusing and defocusing aberrations and the use of photographic detection methods are included. Correction of omissions from earlier theory and modelling is noted, together with observed effects. Incoherent scattering can give dramatic changes in diffracted intensities and significant shifts of final parameters. Effects of depth penetration on shifts, cosine ratios and other parameters are included. Assumptions of the model and implementation are detailed. It is shown that interference effects between waves of roughly equal amplitudes require use of lamellar thicknesses greater than those corresponding to the Darwin range. Internal tests demonstrate agreement with the literature at extremes. The theory is applied to first-and fourth-order spectra in differential Lyman ~ wavelength measurements. Resuits for pentaerythritol 002 crystals are presented. Paper II of this series extends this model to nonideally imperfect crystals and other crystals of interest and discusses experimental agreement.

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Section: Introductionmentioning

confidence: 99%

X-ray diffraction of bent crystals in Bragg geometry. I. Perfect-crystal modelling

Chantler¹

1992

J Appl Cryst

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“…Here they are split into two parts, the outgoing and reflected waves, and so the process continues (Chukhovskii, Gabrielyan & Petrashen', 1978). In other words, wave-field components with sign (aofl) > 0 gain the capability of a 'waveguide' travelling along the entrance surface over large distances, restricted only by their absorption lengths.…”

Section: A New Kind Of Interfermometric Fringe In Bragg Section Topogmentioning

confidence: 99%

“…An analysis of wave-field propagation in the bulk of a crystal can be carried out on the basis of (3.1)-(3.5), like the analysis performed by Balibar, Chukhovskii & Malgrange (1983) (see also Chukhovskii, Gabrielyan & Petrashen', 1978;Chukhovskii, 1981;Gronkowski & Malgrange, 1984) in the Laue diffraction case; it yields the following picture.…”

Section: A New Kind Of Interfermometric Fringe In Bragg Section Topogmentioning

confidence: 99%

“…In the Bragg geometry of X-ray diffraction in a crystal with USG the section-topograph pattern is described with the Green function introduced by Chukhovskii, Gabrielyan & Petrashen' (1978). The expansion of this function as a wave packet takes the form Po~ i°° Gho--dp Ph(P),…”

Section: A New Kind Of Interfermometric Fringe In Bragg Section Topogmentioning

confidence: 99%

“…The dynamical scattering of X-rays (DSXR) in distorted crystals with a uniform strain gradient (USG) has been investigated in a number of studies (Kato, 1964;Bonse, 1964;Penning, 1966;Hart, 1966;Blech & Meieran, 1967;Malgrange, 1969;Ando & Kato, 1970;Petrashen', 1973;Chukhovskii, 1974;Petrashen' & Chukhovskii, 1975;Chukhovskii & Petrashen', 1977;Chukhovskii, Gabrielyan & Petrashen', 1978;Kushnir, Suvorov & Mukhin, 1980;Khrupa, Kislovskii & Datzenko, 1980;Petrashen' & Yaroslavskaya, 1981;Balibar, Chukhovskii & Malgrange, 1983;Shulpina, Petrashen', Chukhovskii & Gabrielyan, 1984) and is a starting point for the quantitative theory of X-ray topographic images and the theory of DSXR in distorted crystals in general.…”

Section: Introductionmentioning

confidence: 99%

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X-ray topography of bent crystals

Chukhovskii¹,

Petrashen²

1988

Acta Cryst Sect A

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The influence of the bending of a crystal on the formation of diffracted images in Bragg section topographs as well as in Laue section and traverse topographs is studied. In the case of Bragg section topography the interferometric fringes due to the interference of waves once and twice internally reflected inside a bent crystal are described. It is established that the maximum positions of diffracted intensity satisfy the law x, = [167r(2n -1)/5B2] 1/3, where x, is the distance from the incidence slit of the X-rays, B is the uniform strain gradient and n is the fringe number. This dependence is found to be in good agreement with experimental data. The Laue section topograph of a bent crystal with a screw dislocation parallel to the diffraction vector is considered. The effects of asymmetry in the Pendell6sung fringe pattern and of 'splitting' of the direct image with respect to the dislocation line in both the experimental and simulated topographs are accounted for. The variation of the contrast of dislocations with depth inside a bent crystal in Laue traverse topographs is studied by computer simulations using the reciprocity theorem.

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Exact solution of the Takagi-Taupin equation for dynamical X-ray bragg diffraction by a crystal with a transition layer

Chukhovskii

Khapachev

1985

phys. stat. sol. (a)

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The dynamical theory of X-ray Bragg diffraction from a crystal with a uniform strain gradient. The Green–Riemann functions

Cited by 79 publications

References 4 publications

X-ray diffraction of bent crystals in Bragg geometry. I. Perfect-crystal modelling

X-ray diffraction of bent crystals in Bragg geometry. I. Perfect-crystal modelling

X-ray topography of bent crystals

Exact solution of the Takagi-Taupin equation for dynamical X-ray bragg diffraction by a crystal with a transition layer

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