0000000001044830

AUTHOR

Jean-marie Lauenstein

showing 12 related works from this author

Heavy-Ion-Induced Degradation in SiC Schottky Diodes : Incident Angle and Energy Deposition Dependence

2017

International audience; Heavy-ion-induced degradation in the reverse leakage current of SiC Schottky power diodes exhibits a strong dependence on the ion angle of incidence. This effect is studied experimentally for several different bias voltages applied during heavy-ion exposure. In addition, TCAD simulations are used to give insight on the physical mechanisms involved.

Nuclear and High Energy PhysicsMaterials scienceSchottky barrierschottky diodesmodelling (creation related to information)01 natural sciencesElectronic mailIonpower semiconductor devicesReverse leakage currentchemistry.chemical_compoundsilicon carbide0103 physical sciencesSilicon carbideElectrical and Electronic Engineering[SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/MicroelectronicsDiode010302 applied physicsta114010308 nuclear & particles physicsbusiness.industrydiodesSchottky diodesiliconmodelingradiationNuclear Energy and EngineeringchemistryionsOptoelectronicsbusinession radiation effectsVoltageIEEE Transactions on Nuclear Science
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Incident angle effect on heavy ion induced reverse leakage current in SiC Schottky diodes

2016

Heavy-ion induced degradation in the reverse leakage current of SiC Schottky power diodes shows distinct dependence on the angle of incidence. TCAD simulations have been used to study the physical mechanisms involved.

Materials scienceSchottky barrierchemistry.chemical_elementSchottky diodes01 natural sciencesIonpower semiconductor devicesReverse leakage currentchemistry.chemical_compoundXenonsilicon carbide0103 physical sciencesSilicon carbidecurrent-voltage characteristicsDiode010302 applied physicsta114ta213010308 nuclear & particles physicsbusiness.industrySchottky diodeAngle of incidencemodelingchemistryOptoelectronicsbusinession radiation effects
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Heavy Ion Induced Degradation in SiC Schottky Diodes : Bias and Energy Deposition Dependence

2017

Experimental results on ion-induced leakage current increase in 4H-SiC Schottky power diodes are presented. Monte Carlo and TCAD simulations show that degradation is due to the synergy between applied bias and ion energy deposition. This degradation is possibly related to thermal spot annealing at the metal semiconductor interface. This thermal annealing leads to an inhomogeneity of the Schottky barrier that could be responsible for the increase leakage current as a function of fluence. peerReviewed

Nuclear and High Energy PhysicsMaterials scienceAnnealing (metallurgy)Schottky barrierschottky diodes01 natural sciencesFluenceIonpower semiconductor deviceschemistry.chemical_compoundsilicon carbide0103 physical sciencesSilicon carbidecurrent-voltage characteristicsElectrical and Electronic EngineeringLeakage (electronics)Diode010302 applied physicsta114ta213010308 nuclear & particles physicsbusiness.industrySchottky diodemodelingNuclear Energy and EngineeringchemistryOptoelectronicsbusinession radiation effectsIEEE Transactions on Nuclear Science
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Failure Estimates for SiC Power MOSFETs in Space Electronics

2018

Silicon carbide (SiC) power metal-oxide-semiconductor field effect transistors (MOSFETs) are space-ready in terms of typical reliability measures. However, single event burnout (SEB) due to heavy-ion irradiation often occurs at voltages 50% or lower than specified breakdown. Failure rates in space are estimated for burnout of 1200 V devices based on the experimental data for burnout and the expected heavy-ion linear energy transfer (LET) spectrum in space. peerReviewed

Materials sciencesingle-event burnoutlcsh:Motor vehicles. Aeronautics. AstronauticsAerospace EngineeringBurnoutpower MOSFETs01 natural scienceschemistry.chemical_compoundReliability (semiconductor)silicon carbide0103 physical sciencesSilicon carbidePower semiconductor devicePower MOSFETheavy ionsavaruustekniikka010302 applied physicspower devicesreliabilityta114ta213010308 nuclear & particles physicsfailure ratessingle event effectsEngineering physicsPower (physics)säteilyfysiikkachemistrytransistoritField-effect transistorlcsh:TL1-4050VoltageAerospace
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Parasitic Bipolar Action in SiC Power MOSFETs Demonstrated by Two-Photon Laser Experiment

2018

A two-photon absorption technique is explored for Silicon carbide power MOSFETs and power junction barrier Schottky diodes using a pulsed laser. The similarities in design between the specific MOSFETs and diodes tested permit using mechanisms existing in the different structures as explanation for observed current variation with laser position. The diode shows variation in average current with change in laser depth only, whereas the MOSFET shows variation both with shifts in depth and shifts in position across the striped geometry of the device. The variation is explained to be due to bipolar amplification of the charge carriers generated in the MOSFET when a pulse focus includes a channel …

010302 applied physicsMaterials science010308 nuclear & particles physicsbusiness.industrySchottky diodeLaser01 natural scienceslaw.inventionchemistry.chemical_compoundchemistrylawLogic gate0103 physical sciencesMOSFETSilicon carbideOptoelectronicsCharge carrierPower MOSFETbusinessDiode2018 18th European Conference on Radiation and Its Effects on Components and Systems (RADECS)
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Enhanced Charge Collection in SiC Power MOSFETs Demonstrated by Pulse-Laser Two-Photon Absorption SEE Experiments

2019

A two-photon absorption technique is used to understand the mechanisms of single-event effects (SEEs) in silicon carbide power metal–oxide–field-effect transistors (MOSFETs) and power junction barrier Schottky diodes. The MOSFETs and diodes have similar structures enabling the identification of effects associated specifically with the parasitic bipolar structure that is present in the MOSFETs, but not the diodes. The collected charge in the diodes varies only with laser depth, whereas it varies with depth and lateral position in the MOSFETs. Optical simulations demonstrate that the variations in collected charge observed are from the semiconductor device structure and not from metal/passiva…

Nuclear and High Energy PhysicsMaterials sciencesingle-event effectsSchottky diodesSemiconductor laser theoryelektroniikkakomponentitchemistry.chemical_compoundsilicon carbideMOSFETSilicon carbidetwo-photon absorptionElectrical and Electronic EngineeringPower MOSFETvertical MOSFETDiodebusiness.industrySchottky diodeSemiconductor deviceNuclear Energy and EngineeringchemistrysäteilyfysiikkatransistoritOptoelectronicsCharge carrierdioditbusinesspulse height analysis
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Unifying Concepts for Ion-Induced Leakage Current Degradation in Silicon Carbide Schottky Power Diodes

2020

The onset of ion-induced reverse leakage current in SiC Schottky diodes is shown to depend on material properties, ion linear energy transfer (LET), and bias during irradiation, but not the voltage rating of the parts. This is demonstrated experimentally for devices from multiple manufacturers with voltage ratings from 600 to 1700 V. Using a device with a higher breakdown voltage than required in the application does not provide increased robustness related to leakage current degradation, compared to using a device with a lower voltage rating.

Nuclear and High Energy PhysicsMaterials science010308 nuclear & particles physicsbusiness.industrySchottky diode01 natural sciencesIonchemistry.chemical_compoundReverse leakage currentNuclear Energy and Engineeringchemistry0103 physical sciencesSilicon carbideOptoelectronicsBreakdown voltageIrradiationElectrical and Electronic EngineeringbusinessDiodeVoltageIEEE Transactions on Nuclear Science
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Estimating Terrestrial Neutron-Induced SEB Cross-Sections and FIT Rates for High-Voltage SiC Power MOSFETs

2019

Cross sections and failure in time rates for neutron-induced single-event burnout (SEB) are estimated for SiC power MOSFETs using a method based on combining results from heavy ion SEB experimental data, 3-D TCAD prediction of sensitive volumes, and Monte Carlo radiation transport simulations of secondary particle production. The results agree well with experimental data and are useful in understanding the mechanisms for neutron-induced SEB data.

Radiation transportSiCcross-sectionNuclear and High Energy PhysicsMaterials scienceMonte Carlo method01 natural sciencesIonpowerchemistry.chemical_compoundMOSFETneutronsilicon carbide0103 physical sciencesMOSFETSilicon carbideNeutronElectrical and Electronic EngineeringPower MOSFETMonte Carlosingle event burnoutta114ta213SEB010308 nuclear & particles physicsHigh voltageFITheavy ionComputational physicsNuclear Energy and Engineeringchemistrysäteilyfysiikkatransistoritfailure in timeMREDIEEE Transactions on Nuclear Science
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Charge Transport Mechanisms in Heavy-Ion Driven Leakage Current in Silicon Carbide Schottky Power Diodes

2016

Under heavy-ion exposure at sufficiently high reverse bias voltages silicon carbide (SiC) Schottky diodes are observed to exhibit gradual increases in leakage current with increasing ion fluence. Heavy-ion exposure alters the overall reverse current-voltage characteristics of these diodes, leaving the forward characteristics practically unchanged. This paper discusses the charge transport mechanisms in the heavy-ion damaged SiC Schottky diodes. A macro model, describing the reverse current-voltage characteristics in the degraded SiC Schottky diodes is proposed. peerReviewed

silicon carbide (SiC)Materials scienceAnnealing (metallurgy)Schottky barrierSchottky diodesMetal–semiconductor junction01 natural sciencesTemperature measurementpower semiconductor deviceschemistry.chemical_compoundstomatognathic system0103 physical sciencesSilicon carbidecurrent-voltage characteristicsElectrical and Electronic EngineeringSafety Risk Reliability and QualityDiode010302 applied physicsta114ta213010308 nuclear & particles physicsbusiness.industrySchottky diodemodelingElectronic Optical and Magnetic MaterialschemistryOptoelectronicsbusinession radiation effectsVoltageIEEE Transactions on Device and Materials Reliability
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Single-Event Burnout Mechanisms in SiC Power MOSFETs

2018

Heavy ion-induced single-event burnout (SEB) is investigated in high-voltage silicon carbide power MOSFETs. Experimental data for 1200-V SiC power MOSFETs show a significant decrease in SEB onset voltage for particle linear energy transfers greater than 10 MeV/cm 2 /mg, above which the SEB threshold voltage is nearly constant at half of the rated maximum operating voltage for these devices. TCAD simulations show a parasitic bipolar junction transistor turn-on mechanism, which drives the avalanching of carriers and leads to runaway drain current, resulting in SEB. peerReviewed

Nuclear and High Energy PhysicsMaterials sciencesingle-event burnoutpower MOSFETs01 natural sciencesdevice simulationselektroniikkakomponentitchemistry.chemical_compoundsilicon carbide0103 physical sciencesMOSFETSilicon carbideElectrical and Electronic EngineeringPower MOSFETheavy ions010302 applied physicspower devicesta114ta213010308 nuclear & particles physicsbusiness.industryionisoiva säteilyBipolar junction transistorsingle event effectsThreshold voltageImpact ionizationsäteilyfysiikkaNuclear Energy and EngineeringchemistrytransistoritOptoelectronicsbusinessCurrent densityVoltageIEEE Transactions on Nuclear Science
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Ion-Induced Energy Pulse Mechanism for Single-Event Burnout in High-Voltage SiC Power MOSFETs and Junction Barrier Schottky Diodes

2020

Heavy-ion data suggest that a common mechanism is responsible for single-event burnout (SEB) in 1200-V power MOSFETs and junction barrier Schottky (JBS) diodes. Similarly, heavy-ion data suggest a common mechanism is also responsible for leakage current degradation in both devices. This mechanism, based on ion-induced, highly localized energy pulses, is demonstrated in simulations and shown to be capable of causing degradation and SEB for both the MOSFETs and JBS diodes.

Nuclear and High Energy PhysicsMaterials science010308 nuclear & particles physicsbusiness.industrySchottky diodeHigh voltage01 natural sciencesIonchemistry.chemical_compoundNuclear Energy and EngineeringchemistryElectric field0103 physical sciencesMOSFETSilicon carbideOptoelectronicsElectrical and Electronic EngineeringPower MOSFETbusinessDiodeIEEE Transactions on Nuclear Science
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Heavy-Ion-Induced Degradation in SiC Schottky Diodes : Incident Angle and Energy Deposition Dependence

2017

Heavy-ion-induced degradation in the reverse leakage current of SiC Schottky power diodes exhibits a strong dependence on the ion angle of incidence. This effect is studied experimentally for several different bias voltages applied during heavy-ion exposure. In addition, TCAD simulations are used to give insight on the physical mechanisms involved. peerReviewed

power semiconductor devicesmallintaminenpiiionitsilicon carbideschottky diodesmodelingdioditsäteilyion radiation effects
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