Abstract :
A numerical model is proposed to simulate plasma immersion ion implantation (PIII) and diffusion. The PIII process is modeled by the 1-D hybrid particle-in-cell ions and Boltzmann distribution of electrons. The depth profile of the as-implanted atoms is modeled by transport-of-ions-in-matter-based method. Diffusion of the implanted atoms is modeled by Fick´s diffusion equation, assuming that the diffusion coefficient is independent of location and time. It is shown that PIII at a high temperature will generate a more shallow depth profile than the process of PIII at low temperature, followed by high-temperature annealing. In the extreme case of fast diffusion, the PIII at high temperature reveals a standard erfc (error function) distribution profile of constant-surface-concentration diffusion, and the process of PIII at low temperature, followed by high-temperature annealing, reveals a Gaussian distribution profile of constant-total-dopant diffusion.
Keywords :
diffusion; ionic conductivity; plasma immersion ion implantation; plasma simulation; 1D hybrid particle in cell simulation; Boltzmann distribution; Fick diffusion equation; PIII process; TRIM method; constant surface concentration diffusion; constant total dopant diffusion; diffusion coefficient; error function distribution profile; fast diffusion; high temperature annealing; implanted atom diffusion; ion transport; numerical simulation; plasma diffusion; plasma immersion ion implantation; transport of ions in matter method; Annealing; Boltzmann distribution; Electrons; Equations; Numerical models; Numerical simulation; Plasma immersion ion implantation; Plasma simulation; Plasma temperature; Temperature distribution; Boltzmann distribution; Fick´s diffusion law; diffusion; numerical simulations; particle-in-cell (PIC); plasma immersion ion implantation (PIII); transport of ions in matter (TRIM);
