Nonparabolic macroscopic transport models for device simulation based on bulk Monte Carlo data

Abstract: We derive higher-order macroscopic transport models for semiconductor device simulation from Boltzmann's transport equation using the method of moments. To obtain a tractable equation set suitable for numerical implementation the validity of the diffusion limit will be assumed which removes the convective terms from the equation system. The infinite hierarchy of equations is then truncated at the orders two ͑drift-diffusion model͒, four ͑energy-transport model͒, and six. Nonparabolicity correction factors are … Show more

“…For simplicity we assume that the energy band is isotropic and parabolic, although generalization to a non-parabolic band is possible [35]. In order to derive the six-moments model, the following weight functions are chosen:…”

“…The energy-transport model requires for each carrier type the modeling of two mobilities for the current density and the energy flux, one relaxation time, and the non-parabilicity factor for non-parabolic bands [35]. Since these models are not always available, a simplified model with the energy flux mobility being proportional or equal to the carrier mobility has been proposed [23,43].…”

“…The scattering rates L mn ðk; k 0 Þ in (35) are related to the rates S mn ðk; k 0 Þ of the original Boltzmann equation via…”

Current transport models for nanoscale semiconductor devices

“…For simplicity we assume that the energy band is isotropic and parabolic, although generalization to a non-parabolic band is possible [35]. In order to derive the six-moments model, the following weight functions are chosen:…”

“…The energy-transport model requires for each carrier type the modeling of two mobilities for the current density and the energy flux, one relaxation time, and the non-parabilicity factor for non-parabolic bands [35]. Since these models are not always available, a simplified model with the energy flux mobility being proportional or equal to the carrier mobility has been proposed [23,43].…”

“…The scattering rates L mn ðk; k 0 Þ in (35) are related to the rates S mn ðk; k 0 Þ of the original Boltzmann equation via…”

Current transport models for nanoscale semiconductor devices

“…Together with the above condition, the kurtosis has to satisfy the inequality 3/5 ≤ β n ≤ 1 [22]. Clearly, β n = 1 corresponds to the energy-transport case for which λ 2 = 0.…”

A Hierarchy of Diffusive Higher-Order Moment Equations for Semiconductors

“…On an engineering level a very efficient way to find approximate solutions of BTE is the method of moments, in comparison to the very time consuming MC technique [2,3]. Considering the first two, four, and six moments, one can obtain the drift-diffusion, the energy-transport, and the six moments model respectively [4]. For these models, an M. Vasicek ( ) · J. Cervenka · M. Wagner · M. Karner · T. Grasser Institute for Microelectronics, TU Wien, Gußhausstraße 27-29, 1040 Vienna, Austria e-mail: vasicek@iue.tuwien.ac.at accurate description of transport parameters like the carrier mobility in the drift-diffusion model is very important.…”

Parameter modeling for higher-order transport models in UTB SOI MOSFETs