Benefits of Considering More than Temperature Acceleration for GaN HEMT Life Testing

Coutu, Ronald A.; Lake, Robert A.; Christiansen, Bradley D.; Heller, Eric R.; Bozada, C.; Poling, B.; Via, G. D.; Theimer, James P.; Tetlak, Stephen E.; Vetury, R.; Shealy, J.B.

doi:10.3390/electronics5030032

Cited by 9 publications

(7 citation statements)

References 19 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The Arrhenius extrapolations reported in the literature [157,169] show extremely long predicted median times that significantly overpredict the actual device lifetime in field applications. This is a major concern in industry because such false prediction may lead to catastrophic events in reliability critical applications [157,168,169]. The overprediction of device lifetime stems from inaccurate estimation of the device peak temperature at the site of degradation/failure during the accelerated high power testing.…”

Section: Nanoscopic Heat Flow Constriction In Wide Bandgapmentioning

confidence: 96%

“…Such failure mechanisms include mechanical damage in the AlGaN barrier due to induction of thermo-elastic stress [159] and thermally assisted interdiffusion at the semiconductor/metal interface [165]. Although GaN HEMTs have been commercialized for small-scale applications (e.g., laptop chargers), questions regarding GaN device thermal reliability remain unanswered [166,167], as evidenced by the continued research into their life expectancies [157,168,169].…”

Section: Nanoscopic Heat Flow Constriction In Wide Bandgapmentioning

confidence: 99%

“…The industry-standard method to estimate GaN HEMT lifetime is the temperature-accelerated direct current operational-life test [170]. The Arrhenius extrapolations reported in the literature [157,169] show extremely long predicted median times that significantly overpredict the actual device lifetime in field applications. This is a major concern in industry because such false prediction may lead to catastrophic events in reliability critical applications [157,168,169].…”

Section: Nanoscopic Heat Flow Constriction In Wide Bandgapmentioning

confidence: 99%

See 2 more Smart Citations

Applications and Impacts of Nanoscale Thermal Transport in Electronics Packaging

Warzoha

Wilson

Donovan

et al. 2021

Journal of Electronic Packaging

View full text Add to dashboard Cite

This review introduces relevant nanoscale thermal transport processes that impact thermal abatement in power electronics applications. Specifically, we highlight the importance of nanoscale thermal transport mechanisms at each layer in material hierarchies that make up modern electronic devices. This includes those mechanisms that impact thermal transport through: (1) substrates, (2) interfaces and 2-D materials and (3) heat spreading materials. For each material layer, we provide examples of recent works that (1) demonstrate improvements in thermal performance and/or (2) improve our understanding of the relevance of nanoscale thermal transport across material junctions. We end our discussion by highlighting several additional applications that have benefited from a consideration of nanoscale thermal transport phenomena, including RF electronics and neuromorphic computing.

show abstract

Section: Nanoscopic Heat Flow Constriction In Wide Bandgapmentioning

confidence: 96%

Section: Nanoscopic Heat Flow Constriction In Wide Bandgapmentioning

confidence: 99%

Section: Nanoscopic Heat Flow Constriction In Wide Bandgapmentioning

confidence: 99%

See 1 more Smart Citation

Applications and Impacts of Nanoscale Thermal Transport in Electronics Packaging

Warzoha

Wilson

Donovan

et al. 2021

Journal of Electronic Packaging

View full text Add to dashboard Cite

show abstract

“…Hence, the reported comparative analysis has not aimed at distinguishing each contribution but at assessing the overall impact of the ambient temperature on the DC and microwave characteristics of the two tested technologies. Nevertheless, for the sake of completeness, it should be underlined that the channel temperature is higher than the ambient temperature because of the heat generated by the self-heating effects, which are strongly dependent not only on the dissipated power level but also on the thickness and thermal conductivity of the materials [13,[29][30][31][32][33][34][35][36]. Furthermore, it is worth mentioning that the extraction of the equivalent-circuit elements may be inevitable affected by the uncertainty inherent in measurements and that, in addition, the model topology itself is an approximation of the device physics [37][38][39][40][41][42][43], which in turn may impact on the achieved temperature-dependent findings.…”

Section: Introductionmentioning

confidence: 99%

Temperature-Sensitivity of Two Microwave HEMT Devices: AlGaAs/GaAs vs. AlGaN/GaN Heterostructures

et al. 2021

View full text Add to dashboard Cite

The goal of this paper is to provide a comparative analysis of the thermal impact on the microwave performance of high electron-mobility transistors (HEMTs) based on GaAs and GaN technologies. To accomplish this challenging goal, the relative sensitivity of the microwave performance to changes in the ambient temperature is determined by using scattering parameter measurements and the corresponding equivalent-circuit models. The studied devices are two HEMTs with the same gate width of 200 µm but fabricated using different semiconductor materials: GaAs and GaN technologies. The investigation is performed under both cooled and heated conditions, by varying the temperature from −40 °C to 150 °C. Although the impact of the temperature strongly depends on the selected operating condition, the bias point is chosen in order to enable, as much as possible, a fair comparison between the two different technologies. As will be shown, quite similar trends are observed for the two different technologies, but the impact of the temperature is more pronounced in the GaN device.

show abstract

“…The acceleration factor (AF), expressed in (1), determines the device lifetime projections and calculates the time acceleration value, that results from operating a device at an elevated temperature. By definition, the AF is the device time to failure at low temperature divided by the time to failure at higher temperature [13],…”

Section: Introductionmentioning

confidence: 99%

Dynamic Temperature Measurements of a GaN DC–DC Boost Converter at MHz Frequencies

Matei

Urbonas²,

Votsi

et al. 2020

IEEE Trans. Power Electron.

View full text Add to dashboard Cite

For reliability predictions, gallium nitride transistors require accurate estimations of the peak operating temperatures within the device. This paper presents a new application of thermoreflectance-based temperature measurements performed on a gallium nitride high electron mobility transistor. The submicron spatial and nanosecond temporal resolutions of the measurement system enables for the first time, the dynamic temperature measurement of a transistor operating up to 5 MHz. The GaN transistor is first biased in class-A and excited with a 1 MHz AC signal to demonstrate the dynamic temperature measurement. The transistor is then incorporated in a 20-40 V DC/DC boost converter to measure the dynamic temperature distributions across the semiconductor die operating under real loading conditions at 1 and 5 MHz switching frequencies. This technique captures the temperature variations that occur during the switching of the transistor and the recorded peak temperatures are 7.4 C higher compared with conventional measurement and simulation approaches. Index Terms-Thermoreflectance measurement, boost converter, gallium nitride, power transistor.

show abstract

Benefits of Considering More than Temperature Acceleration for GaN HEMT Life Testing

Cited by 9 publications

References 19 publications

Applications and Impacts of Nanoscale Thermal Transport in Electronics Packaging

Applications and Impacts of Nanoscale Thermal Transport in Electronics Packaging

Temperature-Sensitivity of Two Microwave HEMT Devices: AlGaAs/GaAs vs. AlGaN/GaN Heterostructures

Dynamic Temperature Measurements of a GaN DC–DC Boost Converter at MHz Frequencies

Contact Info

Product

Resources

About