Interband tunneling is frequently studied using the semiclassical Kane model, despite uncertainty about its validity. Revisiting the physical basis of this formula, we find that it neglects coupling to other bands and underestimates transverse tunneling. As a result, significant errors can arise at low and high fields for small and large gap materials, respectively. We derive a simple multiband tunneling model to correct these defects analytically without arbitrary parameters. Through extensive comparison with band structure and quantum transport calculations for bulk InGaAs, InAs, and InSb, we probe the accuracy of the Kane and multiband formulas and establish the superiority of the latter. We also show that the nonlocal average electric field should be used when applying either of these models to nonuniform potentials. Our findings are important for efficient analysis and simulation of bulk semiconductor devices involving tunneling.

Topics
Quantum confinement, Electronic transport, Band gap, Semiconductors, P-N junctions, Software engineering, Geometric topology, Wentzel-Kramers-Brillouin approximation, Quantum tunneling
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Note that while Eq. (5.16) in Ref. 28 is correct, there is an error of 2 in the coefficients of the remote-band-corrected transmission in Eq. (5.52) of that work.

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