High Current Output Hydrogenated Diamond Triple-Gate MOSFETs

Liu, Jiangwei; Ohsato, Hirotaka; Da, Bo; Koide, Yasuo

doi:10.1109/jeds.2019.2915250

Cited by 8 publications

(2 citation statements)

References 32 publications

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“…Currently, the most commonly used boron-doping method involves introducing borane or trimethyl boron (TMB) during the MPCVD process. By adjusting the ratio of boron-containing gases to carbon-containing gases, different boron doping concentrations can be achieved, effectively controlling the electrical conductivity of diamond (17)(18)(19). MPCVD provides a highly repeatable and uniform boron-doped homoepitaxial growth process for diamond.…”

Section: Introductionmentioning

confidence: 99%

(Invited) Preparation of N-Type and P-Type Doped Single Crystal Diamonds with Laser-Induced Doping and Microwave Plasma Chemical Vapor Deposition

Guo,

Tian,

Wang

et al. 2024

ECS Trans.

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In this study, n-type doped single-crystal diamonds were successfully prepared under normal temperature and pressure conditions using laser-induced doping. 248nm pulsed laser beams with nanosecond duration were irradiated on the single crystal diamond substrate immersing in an 85% phosphoric acid solution and it introduced phosphorus doping to form an n-type doped thin layer. The resistivity of the doped region significantly decreased compared to that of the single-crystal diamond. After depositing a titanium electrode, the resistivity of the doped film obtained by Van der Pauw Technique was determined to be 1.5×10-4 Ω·cm. Furthermore, p-type doped single-crystal diamonds were successfully prepared by introducing boron during the growth process using Microwave Plasma Chemical Vapor Deposition（MPCVD）. It was demonstrated that the proposed technique can introduce impurities into single crystal diamonds to form doped conductive thin layers.

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Section: Introductionmentioning

confidence: 99%

(Invited) Preparation of N-Type and P-Type Doped Single Crystal Diamonds with Laser-Induced Doping and Microwave Plasma Chemical Vapor Deposition

Guo,

Tian,

Wang

et al. 2024

ECS Trans.

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“…This is due to the unique properties of diamond as a wide band-gap (5.5eV) semiconductor. The majority of Diamond field-effect transistors (FETs) fabricated to-date use a 2D hole gas that emerges when an H-terminated diamond surface comes into contact with a range of adsorbates and/or selected metal oxides [1][2][3][4][5][6][7][8]. However, this unconventional manner of creating a ptype region in a semiconductor suffers from instability and reproducibility problems [9] and low operational mobility issues [10][11], although recent progress with the use of metaloxide passivation/gate structures have considerably reduced these problems.…”

Section: Introductionmentioning

confidence: 99%

Normally-OFF Diamond Reverse Blocking MESFET

Canas

Pakpour-Tabrizi

Trajković

et al. 2021

IEEE Trans. Electron Devices

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Schottky contacts have been used to fabricate normally-off lateral reverse-blocking MESFETs on p-type (boron doped) O-terminated monocrystalline diamond. The devices utilized an ohmic source contact but both gate and drain contacts were Schottky in nature. Boron-doped pchannel diamond MESFETs reported to-date display the less-attractive normally-on characteristics.Here, the normally-off transistor delivered a current level of ~1.5 µAmm -1 at a negative VGS of 0.8V and a transconductance (gm) of 16 µSmm -1 , measured at room temperature; at a temperature of 425 K with these values rose to ~70 µAmm -1 for IDS and a gm value of 260 µSmm -1 . In both cases a negligible gate leakage current was measured with no breakdown apparent at the maximum field investigated here (3.7x10 5 V/m -1 ). The Schottky gate demonstrates a well-behaved control of the channel even at higher temperatures. The high temperature operation, normally-off behavior and diamond's inherent radiation hardness make this transistor promising for harsh environment applications.

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