Charge carrier transport in chemical vapor-deposited amorphous SiC/p-type crystalline Si heterostructures has been studied over the temperature range 80–400 K, using current–voltage (I–V), current–temperature (I–T), capacitance–voltage (C–V), and capacitance relaxation (C–t) characteristics. These heterojunctions exhibit high breakdown voltages (230 V) and a diode rectification ratio of 103 at ±0.5 V. At low temperatures (80–120 K) the a-SiC behaves like a dielectric, and the interface built-in voltage can be determined from the capacitance–voltage plot. The corresponding low forward bias current flow is limited by variable-range electron hopping conductivity at Fermi level in the a-SiC layer. At increasing temperature and forward bias voltage, an additional hole current component is found with the transport governed by a multistep tunneling hole emission process through the a-SiC/c-Si heterobarrier. At still higher forward bias voltages (>0.8 V), space-charge-limited hole conduction in the presence of traps in the a-SiC bulk limits transport.
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