Record Responsivity-conductance Performance in Sub-bandgap-triggered Ga2O3 PCSS
Abstract
We present an investigation into the role of anode grid pitch and excitation spectrum on the performance of high-power optoelectronic switches utilizing Fe-doped β-Ga2O3. By systematically varying the anode grid pitch (20-80\ μm) and the excitation spectrum (235-500\ nm), we identify a crucial sub-bandgap regime, centered at 272\ nm, that effectively activates deep-level defect states. This activation is shown to enable highly efficient bulk carrier transport, a significant contrast to conventional above-bandgap excitation which is hampered by shallow surface absorption. The sub-bandgap illumination promotes strong photocurrent generation and substantially improved carrier collection efficiency. Under optimized conditions, specifically utilizing a 40\ μm anode pitch, the fabricated device achieves a high peak photocurrent of 4.14\ A and a record-low on-resistance of 10.4\ Ω. To quantify this simultaneous high-performance achievement, we introduce a responsivity-conductance figure of merit (FoMRC), which attains a record value of 4.7 × 10-6\ S/W. These findings robustly demonstrate the superior suitability of Fe-doped β-Ga2O3 for next-generation high-power optoelectronic switching applications, enabling reliable ampere-level photocurrents coupled with minimized on-resistance through strategic device geometry optimization and sub-bandgap excitation.
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