This work presents the influence of Thin Wafer und Laser Anneal Technology on the electrical performance of 4HSiC devices. Substrate thinning and backside ohmic contact formation via laser annealing were successfully applied to in-house designed and manufactured 6 A 650 V SiC diodes at IISB, improving its forward characteristics. The given devices exhibit an on-state voltage drop (VF) reduction from 1.78 V to 1.62 V at 6 A rated current while maintaining blocking capabilities of more than 1.1 kV with leakage currents less than 1 μA at 650 V nominal voltage. On-resistance (RON) was lowered by approx. 30 % to 90 mΩ and 60 % to 12 mΩ in Schottky and conductivity modulation state, respectively. Wafer thinning also allows reducing the influence of non-homogeneous distributed substrate doping concentrations, leading to a more narrow distribution of the forward characteristics of the devices across the wafer.
In this work, pulsed-laser-based tempering was applied for post-implant annealing of n-type N-doped 4H-SiC in order to electrically activate the dopants and to rebuild the crystal structure. The annealing was performed by a frequency-tripled Nd:YVO4 laser with a pulse duration of 60 ns. To evaluate the effects of post-implant annealing, JBS diodes were electrically characterized. The results were compared with implanted, not post-annealed JBS diodes. The electrical measurements showed a significant on-state voltage drop of 40 mV at 6 A for post-implant laser annealed diodes compared to not post-implant annealed diodes.
The Smart CutTM technology enables the combination of a high quality single crystal SiC layer onto a low resistivity handle wafer (<5mOhm.cm), allowing device optimization as well as the reduction of device’s conduction and switching losses. On this new SmartSiCTM substrate, the sheet resistance of the back side contact after metal deposition, without anneal, is about 10x lower than the annealed back side contact on 4H-SiC. Schottky-barrier vertical structures thinned down to 250μm were prepared for power cycling tests (PCT) measurements. Up to 250 k cycles, the devices remained within the specifications of AQG324 for samples prepared from SmartSiCTM substrates. We are demonstrating here that in addition to a higher current rating (up to 20%), the SmartSiCTM substrate enables a device fabrication simplification by skipping the annealing of the back-side ohmic contact, without compromising either the back-side contact resistance or the assembly PCsec reliability.
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.