Kinetic Monte Carlo simulations for transient thermal fields: Computational methodology and application to the submicrosecond laser processes in implanted silicon

Fisicaro, Giuseppe; Pelaz, Lourdes; López, Pedro; Magna, Antonino La

doi:10.1103/physreve.86.036705

Cited by 19 publications

(9 citation statements)

References 26 publications

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“…Hence, it is mandatory to couple the stochastic method with a phase-field model that properly simulates the rapidly varying non-uniform thermal and phase (if melting occurs) fields. 9) The current version includes dopant atoms that can reside in a substitutional position B s or form a complex with interstitial defects, i.e., BICs. 10) Without loss of generality, we assumed that I and V point defects as well as the BI complex (one dopant atom bound to one I point defect) are the only mobile species, and that defect clusters X m (X = I or V) as well as the dopant-defect cluster B n I m (a cluster formed by n dopant atoms and m interstitials) can only absorb or emit mobile defects.…”

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confidence: 99%

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Kinetic Monte Carlo simulations of boron activation in implanted Si under laser thermal annealing

Fisicaro

Pelaz

Aboy

et al. 2014

Appl. Phys. Express

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We investigate the correlation between dopant activation and damage evolution in boron-implanted silicon under excimer laser irradiation. The dopant activation efficiency in the solid phase was measured under a wide range of irradiation conditions and simulated using coupled phase-field and kinetic Monte Carlo models. With the inclusion of dopant atoms, the presented code extends the capabilities of a previous version, allowing its definitive validation by means of detailed comparisons with experimental data. The stochastic method predicts the post-implant kinetics of the defect-dopant system in the far-from-equilibrium conditions caused by laser irradiation. The simulations explain the dopant activation dynamics and demonstrate that the competitive dopant-defect kinetics during the first laser annealing treatment dominates the activation phenomenon, stabilizing the system against additional laser irradiation steps.

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confidence: 99%

“…The periodic and boundary conditions were set as in Ref. 9. Considering the values of R melt and R p , the choice of a simulation box (X b © Y b © Z b ) with a depth of Z b = 600 nm (in the direction of laser irradiation) reliably approximates a bulk sample.…”

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confidence: 99%

Kinetic Monte Carlo simulations of boron activation in implanted Si under laser thermal annealing

Fisicaro

Pelaz

Aboy

et al. 2014

Appl. Phys. Express

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“…[11]. The projected range of the boron ions (30 keV) is 120 nm and the maximum melt depth corresponding to the highest laser fluence employed (2.6 cm -2 ) is 140 nm, so the choice of a simulation box ( × × ) with a depth of = 600 nm (in the direction of laser laser irradiation) ensures the validity of the real bulk approximation.…”

Section: Kmc For the Dopant-defects Systemmentioning

confidence: 99%

“…The implementation details for the pure defect system can be found in Ref. [11]. Dopant atoms can reside in a substitutional position or form a complex with interstitial defects, i.e.…”

Section: Kmc For the Dopant-defects Systemmentioning

confidence: 99%

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Dopant dynamics and defects evolution in implanted silicon under laser irradiations: A coupled continuum and kinetic Monte Carlo approach

Fisicaro

Pelaz

Aboy

et al. 2013

2013 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD)

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Defect evolution and dopant dynamics in boron implanted silicon under excimer laser irradiation is investigated by means of continuous model and kinetic Monte Carlo (KMC) simulations. Both approaches rule the post-implant kinetics of the defects-dopant system in the extremely far from-the equilibrium conditions caused by the laser irradiation. The thermal problem has been solved within the phase-field methodology. Our model, based on the interaction between defects and the active/inactive impurities, elucidates the dopant activation as well as the observed defect aggregation. Concurrently to the solid-phase problem for the dopant activation, Boron evolution mechanism in silicon melting phase induced by the laser heating have been investigated in details. The analysis suggests an anomalous impurity redistribution in the molten regions induced by the melting laser irradiation related to the mixed (metal+covalent) bonding character of the liquid state. This microscopic mechanism explains the anomalous B segregation whereas accurate comparisons between experimental chemical profiles and simulation results validate the two state diffusion model

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Simulation of the Growth Kinetics in Group IV Compound Semiconductors

Magna

Alberti

Barbagiovanni

et al. 2018

Physica Status Solidi (a)

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A stochastic simulation method designed to study at an atomic resolution the growth kinetics of compounds characterized by the sp3‐type bonding symmetry is presented. Formalization and implementation details are discussed for the particular case of the 3C‐SiC material. A key feature of this numerical tool is the ability to simulate the evolution of both point‐like and extended defects, whereas atom kinetics depend critically on process‐related parameters. In particular, the simulations can describe the surface state of the crystal and the generation/evolution of defects as a function of the initial substrate condition and the calibration of the simulation parameters. Quantitative predictions of the microstructural evolution of the studied systems can be readily compared with the structural characterization of actual processed samples is demonstrated.

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Kinetic Monte Carlo simulations for transient thermal fields: Computational methodology and application to the submicrosecond laser processes in implanted silicon

Cited by 19 publications

References 26 publications

Kinetic Monte Carlo simulations of boron activation in implanted Si under laser thermal annealing

Kinetic Monte Carlo simulations of boron activation in implanted Si under laser thermal annealing

Dopant dynamics and defects evolution in implanted silicon under laser irradiations: A coupled continuum and kinetic Monte Carlo approach

Simulation of the Growth Kinetics in Group IV Compound Semiconductors

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