Power Conversion With SiC Devices at Extremely High Ambient Temperatures

Funaki, Tsuyoshi; Balda, Juan Carlos; Junghans, Jeremy; Kashyap, Avinash S.; Mantooth, H. Alan; Barlow, F.; Kimoto, Tsunenobu; Hikihara, Takashi

doi:10.1109/tpel.2007.900561

Cited by 282 publications

(83 citation statements)

References 17 publications

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“…[2][3][4][5][6][7] Because the application of SiC devices enables high-temperature operation of power converters, the cooling system can be reduced or eliminated. [8][9][10][11][12] As a result, the output power density of power converters can be significantly increased and their weight can be remarkably reduced. To realize high-temperature operation of SiC power devices, high-temperature packaging technologies are crucial.…”

Section: Introductionmentioning

confidence: 99%

Improvement in Joint Reliability of SiC Power Devices by a Diffusion Barrier Between Au-Ge Solder and Cu/Ni(P)-Metalized Ceramic Substrates

Lang

Yamaguchi

Ohashi

et al. 2011

Journal of Elec Materi

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The long-term joint reliability of SiC power devices bonded on a ceramic substrate metalized with copper (Cu) and electroless nickel-phosphorus [Ni(P)] using a gold-germanium (Au-Ge) eutectic solder was investigated at 330°C in air. Rapid growth of Ni-Ge intermetallic compounds (IMCs) at the solder/Ni(P) interface and subsequent oxidation of the conductive Cu layer at the IMCs/Cu interface led to a dramatic decrease in bond strength and an increase in the electrical resistance of the joint. To improve the joint reliability, a 250-nm-thick tungsten (W) diffusion barrier (DB) was prepared on the surface of the substrate using a sputtering process. SiC Schottky barrier diode (SBD) power devices were then die-bonded to the W-DB-modified substrate with the Au-Ge eutectic solder using a vacuum reflow system. The bonded samples were aged at 330°C in air. After 1600 h, the joint strength was two times higher than that on the W-DB-free substrate, and no change was observed in the electrical resistance.

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Section: Introductionmentioning

confidence: 99%

Improvement in Joint Reliability of SiC Power Devices by a Diffusion Barrier Between Au-Ge Solder and Cu/Ni(P)-Metalized Ceramic Substrates

Lang

Yamaguchi

Ohashi

et al. 2011

Journal of Elec Materi

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“…The static and dynamic characteristics of the SiC devices over 400°C are reported in [1,2], and the successful operations of the SiC devices in power electric applications over 300°C are introduced in [3,4]. High temperature operation capability of SiC devices enables to increase power density and reduce a size of a power electronics system.…”

Section: Introductionmentioning

confidence: 99%

Transient thermal analysis of packaged SiC SBDs for high temperature operation

Kim

Funaki

2016

IEICE Electron. Express

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SiC power devices have high temperature operation capability compared to Si power devices. The thermal characteristics of packaged SiC devices are important for thermal management in high temperature range. This study investigates thermal characteristics of a packaged SiC device for high temperature operation. The transient and steady state thermal resistances of the packaged SiC SBDs are measured using JESD51-1 standard. In addition, the numerical thermal simulation of the packaged SiC SBDs using finite difference method (FDM) are carried out considering nonlinear thermal properties of package materials. In the current research, the thermal resistance of the packaged SiC SBD increases by about 10% in the temperature rise from 27°C to 250°C.

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“…However, this not only affects the reverse characteristics, but also modifies the device thermal behavior at forward bias [4]. In contrast with SBD's, whose positive temperature coefficient is dictated by the series resistance [5], JBS thermal behavior is predominated by the bipolar junction, which turns the overall temperature coefficient to negative [4]. Notice that both structures present Schottky and bipolar contacts parallel connected, whose current density balance is dictated by the device temperature [4], which could cause destructive local self-heating effects, especially in high temperature applications [6,7].…”

Section: Introductionmentioning

confidence: 99%