Device formation and the characterizations

David Eon; Hitoshi Umezawa; Takayuki Iwasaki; Takuya Murooka; Mutsuko Hatano; Daniel Araujo; Julien Pernot; Hiroshi Kawarada; Hiromitsu Kato; Toshiharu Makino; Satoshi Koizumi

doi:10.1016/B978-0-08-102183-5.00005-4

Device formation and the characterizations

David Eon, Hitoshi Umezawa, Takayuki Iwasaki, Takuya Murooka, Mutsuko Hatano, Daniel Araujo, Julien Pernot, Hiroshi Kawarada, Hiromitsu Kato, Toshiharu Makino, Satoshi Koizumi

基幹理工学部

研究成果: Chapter

1 被引用数 (Scopus)

抄録

As discussed in Chapter 3, Fundamental material’s nature of diamond, semiconductor diamonds are expected to decrease both conduction and switching losses of power devices. High temperature reliability and radiation hardness are also expected because of the large bandgap and strong covalent bond of diamond. This chapter reviews the state of the art of various devices such as unipolar and bipolar devices, especially Schottky barrier diodes, metal-semiconductor field-effect transistors, junction FETs, metal-oxide-semiconductor field-effect transistors (FETs), pin diodes, and bipolar junction transistors. Novel diamond devices such as Schottky-pn diode and cold cathode emitter, which overcome the trade-off relationship between on-resistance and breakdown voltage, will also be discussed.

本文言語	English
ホスト出版物のタイトル	Power Electronics Device Applications of Diamond Semiconductors
出版社	Elsevier
ページ	295-382
ページ数	88
ISBN（電子版）	9780081021835
ISBN（印刷版）	9780081021842
DOI	https://doi.org/10.1016/B978-0-08-102183-5.00005-4
出版ステータス	Published - 2018 1月 1

ASJC Scopus subject areas

工学（全般）
材料科学（全般）

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10.1016/B978-0-08-102183-5.00005-4

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AU - Eon, David

AU - Umezawa, Hitoshi

AU - Iwasaki, Takayuki

AU - Murooka, Takuya

AU - Hatano, Mutsuko

AU - Araujo, Daniel

AU - Pernot, Julien

AU - Kawarada, Hiroshi

AU - Kato, Hiromitsu

AU - Makino, Toshiharu

AU - Koizumi, Satoshi

PY - 2018/1/1

Y1 - 2018/1/1

N2 - As discussed in Chapter 3, Fundamental material’s nature of diamond, semiconductor diamonds are expected to decrease both conduction and switching losses of power devices. High temperature reliability and radiation hardness are also expected because of the large bandgap and strong covalent bond of diamond. This chapter reviews the state of the art of various devices such as unipolar and bipolar devices, especially Schottky barrier diodes, metal-semiconductor field-effect transistors, junction FETs, metal-oxide-semiconductor field-effect transistors (FETs), pin diodes, and bipolar junction transistors. Novel diamond devices such as Schottky-pn diode and cold cathode emitter, which overcome the trade-off relationship between on-resistance and breakdown voltage, will also be discussed.

AB - As discussed in Chapter 3, Fundamental material’s nature of diamond, semiconductor diamonds are expected to decrease both conduction and switching losses of power devices. High temperature reliability and radiation hardness are also expected because of the large bandgap and strong covalent bond of diamond. This chapter reviews the state of the art of various devices such as unipolar and bipolar devices, especially Schottky barrier diodes, metal-semiconductor field-effect transistors, junction FETs, metal-oxide-semiconductor field-effect transistors (FETs), pin diodes, and bipolar junction transistors. Novel diamond devices such as Schottky-pn diode and cold cathode emitter, which overcome the trade-off relationship between on-resistance and breakdown voltage, will also be discussed.

KW - avalanche mechanism

KW - barrier inhomogeneity

KW - BJT

KW - breakdown voltage

KW - current density

KW - electron emitters

KW - JFET

KW - MESFET

KW - MOSFET

KW - Schottky-pn diode

KW - self-heating

KW - two-dimensional hole gas

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BT - Power Electronics Device Applications of Diamond Semiconductors

PB - Elsevier

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Device formation and the characterizations

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