Showing papers by "Enrico Bellotti published in 1999"
TL;DR: In this paper, the first five conduction bands derived from the pseudopotential method and a numerically calculated impact ionization transition rate using a wave-vector-dependent dielectric function were studied using an ensemble Monte Carlo method.
Abstract: Electronic transport in wurtzite phase InN is studied using an ensemble Monte Carlo method. The model includes the full details of the first five conduction bands derived from the pseudopotential method and a numerically calculated impact ionization transition rate using a wave-vector- dependent dielectric function. Calculated results for electron transport at both low and high electric field are presented and compared with available results from simpler methods. The dependence of the relevant transport properties on the parameters is discussed, in particular in regards to the uncertainties in the band structure and coupling constants. It is found that at a field of 65 kV/cm that the peak electron drift velocity is 4.2×107 cm/s. The peak velocity in InN is substantially higher than in GaN. The velocity field curve presents a noticeable anisotropy with respect to field direction. The peak velocity decreases to 3.4×107 cm/s for a field of 70 kV/cm in the direction perpendicular to the basal plane. The elect...
167 citations
TL;DR: In this paper, the authors presented the first calculation of hole transport in the 3C phase of SiC. The salient features of the model are the full band-structure computed by the empirical pseudopotential method, a numerically calculated hole-phonon scattering rate and the impact ionization transition rates.
Abstract: In this article the first calculation of hole transport in the 3C phase of SiC is presented. The salient features of the model are the full band-structure computed by the empirical pseudopotential method, a numerically calculated hole-phonon scattering rate and the impact ionization transition rates. The coupling constants necessary to determine the scattering rates have been determined either from available data in the literature or by fitting the calculated mobility values to low field experimental results. The impact ionization transition rates have been determined directly from the band-structure based on a wave-vector dependent dielectric function. The steady state drift velocity as a function of the applied electric field strength is computed for different field directions and doping concentrations. The calculated results show the presence of an anisotropy in the drift velocity for the field applied along different directions, similar to what is found in silicon. The maximum values of the velocity a...
45 citations
TL;DR: In this paper, Monte Carlo simulations of electron transport for wurtzite phase GaN in crossed, weak electric and magnetic fields are presented, and it is found that the Hall factor, rH = μHall/μdrift, decreases monotonically as the temperature increases from 77K to 400K.
Abstract: Results of Monte Carlo simulations of electron transport for wurtzite phase GaN in crossed, weak electric and magnetic fields are presented. It is found that the Hall factor, rH = μHall/μdrift, decreases monotonically as the temperature increases from 77K to 400K.The low temperature value of the Hall factor increases significantly with increasing doping concentration. The Monte Carlo simulations take into account the electron-lattice interaction through polar optical phonon scattering, deformation potential acoustic phonon scattering (treated as an inelastic process), and piezoelectric acoustic phonon scattering. Impurity scattering due to ionized and neutral donors is also included, with the latter found to be important at low temperature due to the relatively large donor binding energy which implies considerable carrier freeze-out already at liquid nitrogen temperature. The temperature dependences of the electron concentration, drift mobility, and Hall factor are calculated for donor concentrations equal to 5 × 1016 cm−3, 1017 cm−3, and 5 × 1017 cm−3. The Monte Carlo simulations are compared to classical analytical results obtained using the relaxation-time approximation, which is found to be adequate at low temperatures and sufficiently low carrier concentrations so that inelastic scattering effects due to optical phonons and degeneracy effects are negligible. The influence of dislocations on the Hall factor is discussed briefly.
2 citations
TL;DR: In this paper, ensemble Monte Carlo calculations of electron transport at high applied electric field strengths in bulk, wurtzite phase InN are performed using a full band Monte Carlo simulation that includes a pseudopotential band structure, all of the relevant phonon scattering agents, and numerically derived impact ionization transition rates.
Abstract: Ensemble Monte Carlo calculations of electron transport at high applied electric field strengths in bulk, wurtzite phase InN are presented. The calculations are performed using a full band Monte Carlo simulation that includes a pseudopotential band structure, all of the relevant phonon scattering agents, and numerically derived impact ionization transition rates. The full details of the first five conduction bands, which extend in energy to about 8 eV above the conduction band minimum, are included in the simulation. The electron initiated impact ionization coefficients and quantum yield are calculated using the full band Monte Carlo model. Comparison is made to previous calculations for bulk GaN and ZnS. It is found that owing to the narrower band gap in InN, a lower breakdown field exists than in either GaN or ZnS.