Combined master and Fokker–Planck equations for the modeling of the kinetics of extended defects in Si

A method is proposed to reduce the number of equations and the calculation time of a one-step modeling of the kinetics of extended defects formed after ion implantation of dopants in silicon. The oscillations of the formation energy curves versus the number of atoms of small interstitial defects and...

Full description

Saved in:
Bibliographic Details
Published inSolid-state electronics Vol. 49; no. 7; pp. 1168 - 1171
Main Authors Lampin, E., Ortiz, C.J., Cowern, N.E.B., Colombeau, B., Cristiano, F.
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.07.2005
Elsevier Science
Elsevier
Subjects
Applied sciences
Electronics
Exact sciences and technology
Extended defects
Ion implanted Si
Materials
Modeling
Ion implanted Si
Extended defects
Modeling
Defect density
Master equation
Ion implantation
Doping
Fokker Planck equation
Interstitial
Silicon
p+ n junction
Extended defect
Defect formation
Online AccessGet full text

Cover

More Information
Summary:A method is proposed to reduce the number of equations and the calculation time of a one-step modeling of the kinetics of extended defects formed after ion implantation of dopants in silicon. The oscillations of the formation energy curves versus the number of atoms of small interstitial defects and its smooth evolution for large defects are accounted for combining a master equation with a Fokker–Planck one. The reduction neither affects the prediction of the self-interstitial supersaturation maintained by the extended defects nor the more “reduction sensitive” parameters such as the defect densities and total number of atoms frozen in the defects. The proposed method is a key step on the way from the modeling of physical effects responsible for boron transient enhanced diffusion to the predictive simulation of p +/n junction depths in development environments.
ISSN:0038-1101
1879-2405
DOI:10.1016/j.sse.2005.04.006