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This research investigates how pulsed titanium ion beams affect the diffusion of dopants in silicon.

April 4, 2026

Numerical Modeling of Diffusion Processes in Silicon under Repetitively Pulsed Energy Impact on the Surface of a High-Power Density Titanium Ion Beam

Key Points

This research investigates how pulsed titanium ion beams affect the diffusion of dopants in silicon.
Conducted numerical modeling of thermal and diffusion processes in silicon
Analyzed temperature fields and dopant profiles during titanium ion beam exposure
Varied pulse durations from 100 to 500 µs and ion current densities from 0.5 to 2.5 A/cm2
Found that dopant diffusion intensity is influenced by temperature fields and ion-beam parameters
Characterized the redistribution of dopants based on varying pulse durations and power densities
Quantified dopant transport under conditions ranging from 5 to 25 kW/cm2 of pulsed power density

Abstract

Thermal and diffusion processes in silicon exposed to a repetitively pulsed titanium ion beam with high power density and submillisecond pulse duration were analyzed. Numerical modeling was used to resolve the spatiotemporal evolution of temperature fields in silicon and the depth profiles of the implanted dopant. The results quantify how the intensity of dopant diffusion transport in silicon depends on the temperature fields and ion-beam parameters. The redistribution of the implanted dopant under repetitively pulsed heating is characterized as a function of the pulse duration from 100 to 500 µs, ion current density from 0.5 to 2.5 A/cm2, and pulsed power density from 5 to 25 kW/cm2.

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Numerical Modeling of Diffusion Processes in Silicon under Repetitively Pulsed Energy Impact on the Surface of a High-Power Density Titanium Ion Beam

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Abstract

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