X‐ray diffraction characterization of microdefects in silicon crystals after high‐energy electron irradiation

Molodkin, V. B.; Olikhovskii, S. I.; Len, E. G.; Sheludchenko, B. V.; Lizunova, S. V.; Kyslovskyy, Ye. M.; Vladimirova, T. P.; Kochelab, E. V.; Reshetnyk, O. V.; Dovganyuk, V. V.; Фодчук, І. М.; Lytvynchuk, T. V.; Klad’ko, V. P.; Świątek, Z.

doi:10.1002/pssa.201184253

Cited by 5 publications

(10 citation statements)

References 16 publications

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“…The dynamic diffraction methods used in the studies of complex multilayer crystalline systems showed that these methods allow to determine the profiles of inhomogeneous in‐depth distribution of defects, and thus distinguish the near‐surface layer with a low defect concentration from the deep layer with a high defect concentration. At the same time, the sensitivity of dynamical diffraction methods allows detection of defects with a density of down to ≈10 10 cm −2 , which corresponds to ≈0.0001% of defects in a graphene lattice.…”

Section: Characteristics Of Defects: Results Of Diffraction Methodsmentioning

confidence: 99%

“…Above‐mentioned concepts have been already applied to carry out a nondestructive diagnostic of the structural heterogeneities for multilayer single‐crystal heterosystems: epitaxial films of yttrium iron garnet on the substrate of gadolinium gallium garnet, which are widely used in nanoindustry. However, when structures are significantly thin, especially several layers in thick as a multilayer graphene or even single layer, the use of traditional diffraction patterns is not feasible.…”

Section: Introductionmentioning

confidence: 99%

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Defect‐Pattern‐Induced Fingerprints in the Electron Density of States of Strained Graphene Layers: Diffraction and Simulation Methods

Radchenko

Tatarenko

Lizunov

et al. 2019

Physica Status Solidi (b)

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The paper combines two theoretical approaches – the method of grazing dynamical diffraction (which allows performing the nondestructive structural diagnostics of defects in the near‐surface layers) with efficient numerical simulation method (which enables computation of electron structure in realistically large systems with millions of atoms) – for studying electronic properties in uniaxially strained graphene layers with point defects: impurity atoms. Electron density of states (DOS) is proved sensitive to the direction of uniaxial tensile deformation and configuration of defects. If defects are distributed orderly, the band gap value (estimated from the DOS curves) varies nonmonotonically versus the stretching deformation along zigzag‐edge direction. In this case, the minimal tensile strain required for the band gap opening is found to be smaller than that for defect‐free graphene, and the maximum band gap value is close to that predicted for failure limit of the defect‐free graphene. The obtained results play a significant part for band gap engineering in graphene: via spatial configuring of defects and external tensile stresses.

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Section: Characteristics Of Defects: Results Of Diffraction Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Defect‐Pattern‐Induced Fingerprints in the Electron Density of States of Strained Graphene Layers: Diffraction and Simulation Methods

Radchenko

Tatarenko

Lizunov

et al. 2019

Physica Status Solidi (b)

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“…After irradiation by dose of 4 × 10 15 el/cm 2 the following activation energies of RD are calculated 0.395 eV; 0.53 eV in n-Si and 0.56 eV; 0.66 eV in p-Si which stimulate conductivity because the carriers' mobility has a weak dose dependence. Among many known energetic levels in Si [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15] corresponding to different RD, Figures 2-4 present energetic levels, which are identified to defined levels in literature. For example, the observed level of 0.395 eV can be classified as E-center with location on Ec 0.4 eV in the forbidden gap of Si [7][8][9]12,13], i.e.…”

Section: Resultsmentioning

confidence: 99%

“…There are numerous investigations concerning the influence of irradiations on the properties of solid states (including silicon) which are carried out before and after irradiation [for example [1][2][3][4][5][6][7][8][9][10][11][12][13][14]. The works on studying the properties of solid states directly under the irradiation process are very scarce [15][16][17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

In-Situ Study of Silicon Single Crystals Conductivity under Electron Irradiation

Yeritsyan¹,

Sahakyan²,

Nikoghosyan³

et al. 2012

JMP

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The influence of electron radiation on the properties of semiconducting silicon single crystals (Si)—both n- and p-types (currently one of the most widely applied material in the electronic technology) was studied under the electron irradiation process in-situ in air (in common conditions). Higher value of electro-conductivity (σ) during the irradiation process with respect to after irradiation was observed, which was explained by ionization and capture mechanisms resulting in the formation of non-equilibrium carriers (hole-electron pairs). The kinetics of radiation defects generation, their physical nature, temperature stability and relaxation are examined. Structural radiation defects formation: point and complexes, their influence on the silicon conductivity are considered

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“…2) for the symmetrical Si(333) reflection of characteristic CuK 1 -radiation [47,48]. Additionally, the rocking curves for Si(333) reflection were measured in the -scanning mode by using the TCD with removed analyser crystal.…”

Section: Defect Structure Of the Cz-si Crystal After High-energy Elecmentioning

confidence: 99%

Dynamical Theory of Triple-Crystal X-ray Diffractometry and Characterization of Microdefects and Strains in Imperfect Single Crystals

Molodkin¹,

Olikhovskii²,

Len³

et al. 2016

Metallofiz. Noveishie Tekhnol.

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A short review of basic principles and limitations in obtaining the analytical expressions for the coherent and diffuse scattering intensities measured by the triple-crystal diffractometer (TCD) are presented. Explicit analytical expressions are given for both the diffuse components of TCD profiles and the reciprocal-lattice maps measured within the Bragg diffraction geometry from crystals containing microdefects of several types. These formulas are derived by using the generalized dynamical theory of X-ray scattering by imperfect crystals with randomly distributed microdefects. Some examples demonstrating possibilities of the developed theory for quantitative characterization of structural imperfections in real single crystals are represented. In particular, characteristics of the complicated microdefect structures fabricated in various silicon crystals grown by Czochralski technique and floating-zone melting method are determined by analytical treatment of the measured TCD profiles, rocking curves, and reciprocal space maps.Key words: dynamical scattering, triple-crystal diffractometer, double-crystal diffractometer, microdefects.В роботі представлено короткий огляд основних принципів, що використо-вуються при одержанні аналітичних виразів для когерентної та дифузної інтенсивностей розсіяння, виміряних трикристальним дифрактометром (ТКД). Одержано точні аналітичні вирази для дифузних компонент як ТКД-профілів, так і мап оберненого простору, виміряних у геометрії дифракції за Бреґґом для кристалів, які містять мікродефекти декількох типів. Ці фор-мули одержано при використанні узагальненої динамічної теорії розсіяння Рентґенових променів неідеальними кристалами з випадково розподілени-ми мікродефектами. Представлено деякі приклади, які демонструють мож-ливості розробленої теорії для кількісної характеризації недосконалостей структури в реальних монокристалах. Зокрема, шляхом аналітичного обро-бляння виміряних ТКД-профілів, кривих відбивання і мап оберненого прос-тору визначено характеристики складних структур мікродефектів, створе-них у кристалах силіцію методами Чохральського і зонного топлення.Ключові слова: динамічне розсіяння, трикристальний дифрактометр, двок-ристальний дифрактометр, мікродефекти.В работе представлен краткий обзор основных принципов, используемых при получении аналитических выражений для когерентной и диффузной интенсивностей рассеяния, измеряемых трёхкристальным дифрактомет-ром (ТКД). Получены точные аналитические выражения для диффузных компонент как ТКД-профилей, так и карт обратного пространства, изме-ренных в геометрии дифракции по Брэггу для кристаллов, содержащих микродефекты нескольких типов. Эти формулы получены при использова-нии обобщённой динамической теории рассеяния рентгеновских лучей не-идеальными кристаллами со случайно распределёнными микродефектами. Представлены некоторые примеры, демонстрирующие возможности разра-ботанной теории для количественной характеризации несовершенств структуры в реальных монокристаллах. В частности, путём аналитической обработки измеренных ТКД-...

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X‐ray diffraction characterization of microdefects in silicon crystals after high‐energy electron irradiation

Cited by 5 publications

References 16 publications

Defect‐Pattern‐Induced Fingerprints in the Electron Density of States of Strained Graphene Layers: Diffraction and Simulation Methods

Defect‐Pattern‐Induced Fingerprints in the Electron Density of States of Strained Graphene Layers: Diffraction and Simulation Methods

In-Situ Study of Silicon Single Crystals Conductivity under Electron Irradiation

Dynamical Theory of Triple-Crystal X-ray Diffractometry and Characterization of Microdefects and Strains in Imperfect Single Crystals

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