The mechanism of the recrystallization process in epitaxial GaN under dynamic stress field: atomistic origin of planar defect formation

Das, C. R.; Dhara, Sandip; Hsu, Hsu Cheng; Chen, L. C.; Jeng, Yeau-Ren; Bhaduri, A.K.; Raj, Baldev; Chen, K. H.; Albert, S. K.

doi:10.1002/jrs.2336

Cited by 8 publications

(4 citation statements)

References 27 publications

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“…These high stresses are reported for pressure-induced phase transformations to denser crystalline ͑c-͒ and amorphous forms in monovalently 1 and covalently bonded compound 2 semiconductors along with plastic deformation, leading to recrystallization by annihilation of dislocation in ionic bonded compound semiconductors. 3,4 Phase transformation of Si under controlled pressure is of renewed interest in the age of ion cutting and ion doping to suit microelectromechanical and nanoelectromechanical systems ͑MEMS and NEMS͒ systems. 5 The study of transformation to the high pressure phase has technological importance for having control in the precision micromachining process steps using enhancement of ductility in these systems.…”

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confidence: 99%

Direct observation of amophization in load rate dependent nanoindentation studies of crystalline Si

Das

Dhara

Jeng

et al. 2010

Applied Physics Letters

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Indentation at very low load rate showed region of constant volume with releasing load in crystalline ͑c-͒Si, indicating a direct observation of liquidlike amorphous phase which is incompressible under pressure. Signature of amorphization is also confirmed from load dependent indentation study where increased amount of amorphized phase is made responsible for the increasing elastic recovery of the sample with increasing load. Ex situ Raman study confirmed the presence of amorphous phase at the center of indentation. The molecular dynamic simulation has been employed to demonstrate that the effect of indentation velocities has a direct influence on c-Si during nanoindentation processes.

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confidence: 99%

Direct observation of amophization in load rate dependent nanoindentation studies of crystalline Si

Das

Dhara

Jeng

et al. 2010

Applied Physics Letters

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“…The stress can reach very high values locally (as evidenced through wavenumber shifts) and the Raman study of micro/nano-indentations is a possible way of monitoring phase transitions under non hydrostatic stress [140,141]. Mapping capabilities are a great asset as the pressure conditions vary from one point to another (the imprints dimensions are in the range of a few tens of micrometers) because of the imperfect geometry of the indenters, the possibility of intragranular versus intergranular indentation, crack propagation at the imprints corners, materials pileup at the imprint periphery, etc., [38,44,[141][142][143][144][145][146][147][148]. Figure 3.20 illustrates the Raman mapping of a Vickers microindentation in ZnSe.…”

Section: Raman Mapping Of Micro-indented Samplesmentioning

confidence: 99%

Raman Mapping for the Investigation of Nano-phased Materials

et al. 2012

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Nanosized and nanophased materials exhibit special properties. First they offer a good compromise between the high density of chemical bonds by unit volume, needed for good mechanical properties and the homogeneity of amorphous materials that prevents crack initiation. Second, interfaces are in very high concentration and they have a strong influence on many electrical and redox properties. The analysis of nanophased, low crystallinity materials is not straigtforward. The recording of Raman spectra with a geometric resolution close to 0.5 µm 3 and the deep understanding of the Raman signature allow to locate the different nanophases and to predict the properties of the material. Case studies are discussed: advanced polymer fibres, ceramic fibres and composites, textured piezoelectric ceramics and corroded (ancient) steel. 3.1 Raman Spectroscopy and (Nano)materials Properties Nanosized and nanophased materials possess a high concentration of interfaces, which results in unique optical and redox properties, as well as a good resistance to crack propagation. Not all conventional materials science research techniques are

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“…The IR and Raman spectra of anhydrous lead oxalate (PbC 2 O 4 ) were recorded and discussed by Mancilla et al 214 on the basis of its structural peculiarities, and comparisons with other previously investigated metallic oxalates were made. Das et al 215 have studied the mechanism of the recrystallization in epitaxial GaN under a dynamic stress field and described the atomic origin of its planar defect formation. SiC is often used for electronic devices operating at elevated temperatures.…”

Section: Solid‐state Studiesmentioning

confidence: 99%

Recent advances in linear and nonlinear Raman spectroscopy. Part IV

Nafie

2010

J Raman Spectroscopy

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The purpose of the review is to provide a concise overview of recent advances in the broadly defined field of Raman spectroscopy as reflected in part by the many articles published each year in the Journal of Raman Spectroscopy (JRS) as well as in trends across all related journals publishing in this research area. Context for the review is provided by considering statistical data on citations for the Thompson Reuters ISI Web of Science by year and by subfield of Raman spectroscopy. Additional statistics of number of papers and posters presented by category at the XXII International Conference on Raman Spectroscopy (ICORS 2010) is also provided. Papers published in JRS in 2009, as reviewed here, reflect trends at the cutting edge of Raman spectroscopy which is expanding rapidly as a sensitive photonic probe of matter at the molecular level with an ever widening sphere of novel applications.

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The mechanism of the recrystallization process in epitaxial GaN under dynamic stress field: atomistic origin of planar defect formation

Cited by 8 publications

References 27 publications

Direct observation of amophization in load rate dependent nanoindentation studies of crystalline Si

Direct observation of amophization in load rate dependent nanoindentation studies of crystalline Si

Raman Mapping for the Investigation of Nano-phased Materials

Recent advances in linear and nonlinear Raman spectroscopy. Part IV

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