A new theory of semiconductor devices, called “semiconductor superjunction (SJ) theory”, is presented. To overcome the trade-off relationship between breakdown voltage and on-resistance of conventional semiconductor devices, SJ devices utilize a number of alternately stacked, p- and n-type, heavily doped, thin semiconductor layers. By controlling the degree of doping and the thickness of these layers, according to the SJ theory, this structure operates as a pn junction with low on-resistance and high breakdown voltage. Analytical formulas for the ideal specific on-resistance and the ideal breakdown voltage of SJ devices are theoretically derived. Analysis based on the formulas and device simulations reveals that the on-resistance of SJ devices can be reduced to less than 10-2 that of conventional devices.
Performances of majority-and minority-carrier semiconductor superjunction devices are examined and compared to that of standard devices in terms of forward current density, reverse leakage current, and switching charge. Based on twodimensional simulations and theoretical calculations, it is shown that two orders of magnitude improvement in forward current density, an order of magnitude improvement in switching charge for majority-carrier superjunction devices, and an order of magnitude improvement in forward current density for minority-carrier superjunction devices are feasible when compared to standard devices.
A new, cost-effective, high-voltage interconnection technique for very high-voltage IC's, called the “self-shielding technique”, is proposed. To avoid reduction of the breakdown voltage of high-voltage devices due to the electric potential of overlying interconnections, only the self-PN-junction structures of the high-voltage devices themselves are utilized in the self-shielding technique. No additional shielding structure is required, even to realize a very high-voltage IC above 1000 V. The design concept and device structures are presented with the experimental results on the electrical characterictics of self-shielded interconnections and on the operations of self-shielded 1200-V level shifters. Comparison between self-shielded and conventional high-voltage IC's (HVIC's) and the process and the devices of self-shielded HVIC technology are also described.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.