Bamer, B., Leroch, S., Hossinger, A., & Filipovic, L. (2024). Cluster-Based Semi-Empirical Model for Dopant Activation in Silicon Carbide. In 2024 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD) (pp. 1–4). https://doi.org/10.1109/SISPAD62626.2024.10732978
International Conference on Simulation of Semiconductor Processes and Devices (SISPAD)
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Event date:
24-Sep-2024 - 27-Sep-2024
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Event place:
San Jose, CA, United States of America (the)
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Number of Pages:
4
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Peer reviewed:
Yes
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Keywords:
annealing; dopant activation; ion implantation; nanoscale clusters; process simulation; Silicon carbide
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Abstract:
We present a cluster-based semi-empirical model for dopant activation in silicon carbide (SiC). We model the following species: dopants on lattice points, point defects, dopant-defect pairs, and small clusters of different sizes. We define the possible reactions between these species, add their reaction kinetics, and use a system of ordinary differential equations (ODEs) to model the time evolution of the concentration of the different species during annealing. We use the MaxLIPO+TR optimizer to obtain the post-implant conditions of the SiC film, including the various cluster concentrations. These concentrations are not measurable and can only be calculated through time-intensive atomistic simulations, which we apply to verify and calibrate our model. The framework presented here, consisting of an ODE model generator, an ODE solver and an optimizer, gives a practical solution to predict as-implanted defect concentrations, which is missing from previous works.
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Project title:
Multi-Scale-Prozessmodellierung von Halbleiter-Bauelemente und -Sensoren: 00000 (Christian Doppler Forschungsgesells)
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Research Areas:
Modeling and Simulation: 70% Computational Materials Science: 30%
