A physically based model for the spatial and temporal evolution of self-interstitial agglomerates in ion-implanted silicon

Ortiz, C.J.; Pichler, P.; Fühner, Tim; Cristiano, F.; Colombeau, B.; Cowern, N.E.B.; Claverie, A.

doi:10.1063/1.1786678

Cited by 68 publications

(40 citation statements)

References 42 publications

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“…Still, it is worth discussing briefly a particular extended defect known as the {311} defect. {311} defects have been studied in much detail [15,[62][63][64][65]. They are rod-shaped accumulations of Si i s in {311} planes of the Si lattice (see Fig.…”

Section: {311} Defectsmentioning

confidence: 99%

Silicon as an emissive optical medium

Shainline

2007

Laser & Photonics Reviews

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One of the great challenges in photonics has been to modify silicon to enhance light emission properties. In this review article we survey recent studies which have generated light from silicon in a variety of ways including introduction of emissive centers, anodization, fabrication of quantum-confined structures and by utilizing non-linear effects. Each method offers insight into silicon as an emissive medium, but no one method has proven effective enough a light source to compete with established technologies based on III-V and II-VI compound semiconductors, and in particular no one method of inducing light emission in silicon has made possible an electrically-pumped silicon laser.Photoluminescence spectra from nanopatterned silicon superimposed on a scanning electron micrograph of the emissive structure.

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Section: {311} Defectsmentioning

confidence: 99%

Silicon as an emissive optical medium

Shainline

2007

Laser & Photonics Reviews

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“…Within this approach based on the mean-field approximation, the diffusion and nucleation/growth of defects is modelled through a set of diffusion-reaction rate equations. Different research teams [11,14,18,23,26] have used this approach to study the nucleation and growth of defects in various materials over the years. Recently, Rottler et al [20] used the RT formalism to investigate point defect dynamics in metals and showed that, when defects are homogeneously distributed, kMC and RT models are in near perfect agreement.…”

Section: Introductionmentioning

confidence: 99%

Cascade damage evolution: rate theory versus kinetic Monte Carlo simulations

Ortiz

Caturla

2007

J Computer-Aided Mater Des

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The thermal evolution of defects produced by ion irradiation is studied by kinetic Monte Carlo and Rate Theory approaches. An isochronal annealing is simulated to evidence the different thermally activated mechanisms that govern defect evolution. KMC simulations show that in the case of ion irradiation, additional recovery peaks should be expected, in comparison to electron irradiation conditions. A comparison between kMC and RT results indicates that some of these peaks are due to spatially -correlated recombinations that occur at low temperature. Therefore kMC and RT approaches differ at low temperature. However, at higher temperature results obtained by both models are in near perfect agreement. In addition, we studied the influence of vacancy cluster mobility on the evolution of damage. KMC simulations show that the mobility of V 2 , V 3 and V 4 clusters does not significantly affect the evolution of defects and can be neglected in these conditions.

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“…Indeed, the same two types of dislocation loops were found in silicon after ''irradiation", actually ion implantation, and it took us a while and lots of experiments to understand then model the formation and thermal evolution of these defects. Today, it is understood and physically based models exist, either analytical or based on Monte Carlo methods, which have been implemented in academic and commercial codes aimed at predicting the effect of processes in semiconductors [2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%