The model has been used to perform circuit-performance comparison with the standard digital library cells between CMOS random logic and CNFET random logic. It accounts for several practical non-idealities, including the scattering of carriers due to the acoustic and optical phonons in the nanotubes, the parasitic capacitance between the gate and the source/drain formed by multiple 1D nanotubes, the gate-to-gate and gate-to-contact-plug capacitances, the charge screening among the adjacent nanotubes, the access resistance of the source/drain extension regions, the Schottky-barrier resistance at the metal-nanotube contact interfaces, and the band-to-band leakage current. The model is based on a quasi-ballistic transport picture and includes an accurate description of the capacitor network in a CNFET. Each device may have one or more carbon nanotubes with user-specified chirality, and the effects of channel length scaling can be accurately modeled down to 20nm. The Stanford University CNFET Model is a SPICE-compatible compact model which describes enhancement-mode, unipolar MOSFETs with semiconducting single-walled carbon nanotubes as channels. Note: A newer version of CNFET compact model, VS-CNFET model, includes data-calibrated metal-to-CNT contact resistance and direct source-to-drain tunneling current, suitable for the study of ultra-scaled CNFETs (e.g.
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