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Main Authors: Li, Yuchen, Chen, Zhizhong, Deng, Chuhan, Dong, Boyan, Wang, Daqi, Pan, Zuojian, Zhang, Haodong, Nie, Jingxin, Chen, Weihua, Jiao, Fei, Kang, Xiangning, Wang, Qi, Zhang, Guoyi, Shen, Bo, Liang, Wenji
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.16626
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author Li, Yuchen
Chen, Zhizhong
Deng, Chuhan
Dong, Boyan
Wang, Daqi
Pan, Zuojian
Zhang, Haodong
Nie, Jingxin
Chen, Weihua
Jiao, Fei
Kang, Xiangning
Wang, Qi
Zhang, Guoyi
Shen, Bo
Liang, Wenji
author_facet Li, Yuchen
Chen, Zhizhong
Deng, Chuhan
Dong, Boyan
Wang, Daqi
Pan, Zuojian
Zhang, Haodong
Nie, Jingxin
Chen, Weihua
Jiao, Fei
Kang, Xiangning
Wang, Qi
Zhang, Guoyi
Shen, Bo
Liang, Wenji
contents This study establishes a unified framework for interpreting dynamic capacitive responses in InGaN-based light-emitting diodes (LEDs) through forward-bias capacitance-voltage-frequency spectroscopy. A hybrid impedance model integrating series RL components and parallel C-G networks was developed to resolve distinct frequency-dependent capacitive regimes. The low-frequency regime (<1 kHz) is governed by interfacial capacitance with characteristic reciprocal frequency dependence, while the mid-frequency range(10 kHz-6.4 MHz) demonstrates carrier diffusion and recombination dynamics. At MHz frequencies, negative capacitance manifests due to delayed carrier emission mediated by deep-level traps. The model achieved sub-1% fitting errors (R^2 > 0.99)across a broad bandwidth(10 kHz-6.4 MHz) , conclusively attributing negative capacitance to intrinsic trap processes rather than extrinsic artifacts. Critical advances include quantum well cap thickness modulation reducing mid-frequency capacitance by 30% and the dominance of trap-mediated inductance over parasitic contributions by three orders of magnitude. This framework resolves persistent controversies in LED impedance interpretation. By bridging semiconductor physics with device engineering, this methodology provides essential tools for designing next-generation optoelectronic systems requiring ultralow-latency operation and precise charge-state control.
format Preprint
id arxiv_https___arxiv_org_abs_2411_16626
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Frequency-Resolved Forward Capacitance in GaN-based LEDs
Li, Yuchen
Chen, Zhizhong
Deng, Chuhan
Dong, Boyan
Wang, Daqi
Pan, Zuojian
Zhang, Haodong
Nie, Jingxin
Chen, Weihua
Jiao, Fei
Kang, Xiangning
Wang, Qi
Zhang, Guoyi
Shen, Bo
Liang, Wenji
Applied Physics
This study establishes a unified framework for interpreting dynamic capacitive responses in InGaN-based light-emitting diodes (LEDs) through forward-bias capacitance-voltage-frequency spectroscopy. A hybrid impedance model integrating series RL components and parallel C-G networks was developed to resolve distinct frequency-dependent capacitive regimes. The low-frequency regime (<1 kHz) is governed by interfacial capacitance with characteristic reciprocal frequency dependence, while the mid-frequency range(10 kHz-6.4 MHz) demonstrates carrier diffusion and recombination dynamics. At MHz frequencies, negative capacitance manifests due to delayed carrier emission mediated by deep-level traps. The model achieved sub-1% fitting errors (R^2 > 0.99)across a broad bandwidth(10 kHz-6.4 MHz) , conclusively attributing negative capacitance to intrinsic trap processes rather than extrinsic artifacts. Critical advances include quantum well cap thickness modulation reducing mid-frequency capacitance by 30% and the dominance of trap-mediated inductance over parasitic contributions by three orders of magnitude. This framework resolves persistent controversies in LED impedance interpretation. By bridging semiconductor physics with device engineering, this methodology provides essential tools for designing next-generation optoelectronic systems requiring ultralow-latency operation and precise charge-state control.
title Frequency-Resolved Forward Capacitance in GaN-based LEDs
topic Applied Physics
url https://arxiv.org/abs/2411.16626