Title :
Measurements and modeling of the n-channel MOSFET inversion layer mobility and device characteristics in the temperature range 60-300 K
Author :
Huang, Cheng-Liang ; Gildenblat, Gennady Sh
Author_Institution :
Center for Electr. Mater. Process., Pennsylvania State Univ., University Park, PA, USA
fDate :
5/1/1990 12:00:00 AM
Abstract :
Discussed is the use of the high-frequency split C-V method to measure accurately the effective mobility of the n-channel MOS transistor as a function of temperature, bulk charge Q b, and inversion layer charge Qi. The experimental data for Qb and Qi were verified by comparison with the results of numerical simulation. The results of the measurements were used to develop the mobility model, which is accurate in the 60-300 K temperature range. The proposed mobility model incorporates Coulombic, lattice, and surface roughness scattering modes and generalizes the previous model, which was limited to low-temperature operation of the MOSFET. The deviation from the universal (for different back biases) μ(Eeff) dependence, which becomes more pronounced at low temperatures and low Eeff, is included in the model and can be associated with the Coulomb scattering mechanism. The proposed model is verified by comparison of experimental data and simulated MOSFET I-V characteristics for different temperatures
Keywords :
capacitance; carrier mobility; insulated gate field effect transistors; inversion layers; semiconductor device models; semiconductor device testing; 60 to 300 K; Coulombic scattering; I-V characteristics; high-frequency split C-V method; inversion layer charge; inversion layer mobility; lattice scattering; modeling; n-channel MOS transistor; n-channel MOSFET; numerical simulation; surface roughness scattering; Charge measurement; Current measurement; Lattices; MOSFET circuits; Numerical simulation; Q measurement; Rough surfaces; Scattering; Surface roughness; Temperature distribution;
Journal_Title :
Electron Devices, IEEE Transactions on
