电调制通过GaN膜上的VO2薄膜传输红外光

Ferhat Bayram, D. Gajula, Balaadithya Uppalapati, Digangana Khan, G. Koley
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引用次数: 0

摘要

近年来,开发用于成像和传感的近红外光调制器的研究备受关注。本文报道了在GaN膜上生长用于光调制的电致变色VO2薄膜的相变诱导光学透过率特性的变化。利用电场作用于沉积在VO2薄膜上的互指金属电极,触发了VO2薄膜的绝缘体金属过渡相。电压触发相变导致薄膜电阻变化约45%,1550 nm激光器的透射光功率降低约11%。此外,通过施加脉冲宽度为2 ms至300µs的不同电压,证明了利用VO2薄膜基膜的IMT特性进行近红外光调制。
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Electrical Modulation Tramsmitted IR Light Through VO2 Thin Film on GaN Membranes
In the recent years, studies to develop near-infrared light modulators for imaging and sensing applications have attracted great attention. Here, we report on phase transition induced optical transmittance characteristics variation of electrochromic VO2 thin film grown on GaN membrane for light modulation application. Insulator metal transition (IMT) phase of the VO2 thin film was triggered using an electric field applied on the interdigitated metal electrodes deposited on it. Voltage triggered phase transition resulted in ~45% change in resistance of the thin film and ~11% reduction in transmitted optical power for a 1550 nm laser. Moreover, near-infrared light modulation utilizing IMT properties of the VO2 thin film-based membrane was demonstrated by applying various voltages with pulse widths ranging from 2 ms to 300 µs,
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