Doo Hyung Cho scite author profile

Doo Hyung Cho

2Publications

0Citation Statements Received

29Citation Statements Given

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Electronics and Telecommunications Research Institute

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Diode and MOSFET Properties of Trench-Gate-Type Super-Barrier Rectifier with P-Body Implantation Condition for Power System Application

Won¹,

Park²,

Cho³

et al. 2016

ETRI J

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In this paper, we investigate the electrical characteristics of two trench‐gate‐type super‐barrier rectifiers (TSBRs) under different p‐body implantation conditions (low and high). Also, design considerations for the TSBRs are discussed in this paper. The TSBRs’ electrical properties depend strongly on their respective p‐body implantation conditions. In the case of the TSBR with a low p‐body implantation condition, it exhibits MOSFET‐like properties, such as a low forward voltage (VF) drop, high reverse leakage current, and a low peak reverse recovery current owing to a majority carrier operation. However, in the case of the TSBR with a high p‐body implantation condition, it exhibits pn junction diode–like properties, such as a high VF, low reverse leakage current, and high peak reverse recovery current owing to a minority carrier operation. As a result, the TSBR with a low p‐body implantation condition is capable of operating as a MOSFET, and the TSBR with a high p‐body implantation condition is capable of operating as either a pn junction diode or a MOSFET, but not both at the same time.

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Human body model electrostatic discharge tester using metal oxide semiconductor‐controlled thyristors

Jung

Park

Kim³

et al. 2022

ETRI Journal

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Electrostatic discharge (ESD) testing for human body model tests is an essential part of the reliability evaluation of electronic/electrical devices and components. However, global environmental concerns have called for the need to replace the mercury-wetted relay switches, which have been used in ESD testers. Therefore, herein, we propose an ESD tester using metal oxide semiconductor-controlled thyristor (MCT) devices with a significantly higher rising rate of anode current (di/dt) characteristics. These MCTs, which have a breakdown voltage beyond 3000 V, were developed through an in-house foundry. As a replacement for the existing mercury relays, the proposed ESD tester with the developed MCT satisfies all the requirements stipulated in the JS-001 standard for conditions at or below 2000 V. Moreover, unlike traditional relays, the proposed ESD tester does not generate resonance; therefore, no additional circuitry is required for resonant removal. To the best of our knowledge, the proposed ESD tester is the first study to meet the JS-001 specification by applying a new switch instead of an existing mercury-wetted relay.K E Y W O R D S electrostatic discharge tester, high rate of rising of anode current (di/dt), human body model, mercury-wetted relay, metal oxide semiconductor-controlled thyristor

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Doo Hyung Cho

Diode and MOSFET Properties of Trench-Gate-Type Super-Barrier Rectifier with P-Body Implantation Condition for Power System Application

Human body model electrostatic discharge tester using metal oxide semiconductor‐controlled thyristors

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