SPICE Modeling and Performance Analysis of Enhancement-Mode GaN HEMTs for Augmented Hard-Switching Energy Conversion Efficiency

IF 0.6 Q3 MULTIDISCIPLINARY SCIENCES Pertanika Journal of Science and Technology Pub Date : 2024-04-04 DOI:10.47836/pjst.32.3.14

X. Liu, S. Shafie, M. A. Mohd Radzi, N. Azis, N. Norddin, Ismail Lawal, Normaziah Zulkifli, Abdul Hafiz Abdul Karim

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Abstract

The advancement of renewable energy sources necessitates the development of effective power electronic devices. Enhancement-mode Gallium Nitride (E-GaN) high-electron-mobility transistors (HEMTs), an emerging wide-bandgap semiconductor device, demonstrate potential in photovoltaic (PV) energy converting applications to enhance power transfer efficiency. This paper discusses the enhanced semiconducting characteristics of GaN HEMT over conventional silicon power devices by analyzing spontaneous and piezoelectric polarizations of wurtzite GaN crystalline structure and the formation of two-dimensional electron gas (2DEG). The lateral device structure of E-GaN HEMT and normally switched-on depletion mode GaN HEMT are compared. A device-under-test (DUT) equivalent model incorporating parasitic components is proposed, adopting the EPC2204 Level 3 SPICE model. The model is simulated in a novel Double Pulse Test (DPT) topology with clamping and snubber subcircuits using LTSPICE software. The performance of GaN E-HEMT is compared to a MOSFET with similar parameters, and the impact of parasitic inductances and stray capacitances is evaluated through switching analysis. Findings support the potential of E-GaN HEMTs and indicate the DC-DC converter design considerations for portable solar PV system applications.

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用于提高硬开关能量转换效率的增强型 GaN HEMT 的 SPICE 建模和性能分析

可再生能源的发展要求开发有效的电力电子器件。增强型氮化镓（E-GaN）高电子迁移率晶体管（HEMT）是一种新兴的宽带隙半导体器件，在光伏（PV）能量转换应用中具有提高功率传输效率的潜力。本文通过分析晶格氮化镓晶体结构的自发极化和压电极化以及二维电子气（2DEG）的形成，讨论了与传统硅功率器件相比，氮化镓 HEMT 增强的半导体特性。比较了 E-GaN HEMT 和正常开关导通耗尽模式 GaN HEMT 的横向器件结构。采用 EPC2204 Level 3 SPICE 模型，提出了一个包含寄生元件的待测器件（DUT）等效模型。使用 LTSPICE 软件在带有箝位和缓冲子电路的新型双脉冲测试 (DPT) 拓扑中对该模型进行了仿真。GaN E-HEMT 的性能与具有类似参数的 MOSFET 进行了比较，并通过开关分析评估了寄生电感和杂散电容的影响。研究结果支持 E-GaN HEMT 的潜力，并指出了便携式太阳能光伏系统应用中直流-直流转换器设计的注意事项。

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来源期刊

Pertanika Journal of Science and Technology MULTIDISCIPLINARY SCIENCES-

CiteScore

1.50

自引率

16.70%

发文量

178

期刊介绍： Pertanika Journal of Science and Technology aims to provide a forum for high quality research related to science and engineering research. Areas relevant to the scope of the journal include: bioinformatics, bioscience, biotechnology and bio-molecular sciences, chemistry, computer science, ecology, engineering, engineering design, environmental control and management, mathematics and statistics, medicine and health sciences, nanotechnology, physics, safety and emergency management, and related fields of study.