Abstract
An analytical model was developed to calculate the potential distribution for a gate-underlap double-gate tunnel FET. The electrostatic potential of the device was derived using the two-dimensional Poisson’s equation, incorporating the fringing electric field in the gate-underlap surface and employing a conformal mapping method. In addition to analytical potential modeling, the electric field and drain current were evaluated to investigate the device performance. Excellent agreement with technology computer-aided design (TCAD) simulation results was observed. The dependence of the ambipolar current on the spacer oxide dielectric constant, spacer length, channel length, and gate material thickness was examined using the proposed model. The effects of the variation of all of these parameters were well predicted, and the model reveals that use of a low-
κ
spacer dielectric combined with a high-
κ
gate dielectric results in the minimal ambipolar current for the device.