Mathematical Problems in Semiconductor Physics Lectures given at the C.I.M.E. Summer School held in Cetraro, Italy, July 15-22, 1998. With the collaboration of G. Mascali and V. Romano. [electronic resource] :
- Berlin, Heidelberg : Springer Berlin Heidelberg, 2003.
- XII, 152 p. online resource.
- Lecture Notes in Mathematics, Fondazione C.I.M.E., Firenze, 1823 0075-8434 ; .
- Lecture Notes in Mathematics, Fondazione C.I.M.E., Firenze, 1823 .
Preface -- A. M. Anile, G. Mascali, V. Romano: Recent Developments in Hydrodynamical Modelling of Semiconductors -- W. Allegretto: Drift-Diffusion Equations and Applications -- C. Ringhofer: Kinetic and Gas-Dynamic Models for Semiconductor Transport.
The C.I.M.E. session on Mathematical Problems in Semiconductor Physics, was addressed to researchers with a strong interest in the mathematical aspects of the theory of carrier transport in semiconductor devices. The subjects covered include hydrodynamical models for semiconductors based on the maximum entropy principle of extended thermodynamics, mathematical theory of drift-diffusion equations with applications, and the methods of asymptotic analysis.
9783540452225
10.1007/b13405 doi
Physics.
Computer aided design.
Differential equations, partial.
Computer science--Mathematics.
Mathematical physics.
Optical materials.
Physics.
Mathematical Methods in Physics.
Optical and Electronic Materials.
Computer-Aided Engineering (CAD, CAE) and Design.
Partial Differential Equations.
Computational Mathematics and Numerical Analysis.
Theoretical, Mathematical and Computational Physics.
QC5.53
530.15
Preface -- A. M. Anile, G. Mascali, V. Romano: Recent Developments in Hydrodynamical Modelling of Semiconductors -- W. Allegretto: Drift-Diffusion Equations and Applications -- C. Ringhofer: Kinetic and Gas-Dynamic Models for Semiconductor Transport.
The C.I.M.E. session on Mathematical Problems in Semiconductor Physics, was addressed to researchers with a strong interest in the mathematical aspects of the theory of carrier transport in semiconductor devices. The subjects covered include hydrodynamical models for semiconductors based on the maximum entropy principle of extended thermodynamics, mathematical theory of drift-diffusion equations with applications, and the methods of asymptotic analysis.
9783540452225
10.1007/b13405 doi
Physics.
Computer aided design.
Differential equations, partial.
Computer science--Mathematics.
Mathematical physics.
Optical materials.
Physics.
Mathematical Methods in Physics.
Optical and Electronic Materials.
Computer-Aided Engineering (CAD, CAE) and Design.
Partial Differential Equations.
Computational Mathematics and Numerical Analysis.
Theoretical, Mathematical and Computational Physics.
QC5.53
530.15