0000000001044831

AUTHOR

Michele Muschitiello

showing 8 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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Semi-Empirical Model for SEGR Prediction

2013

The underlying physical mechanisms in single event gate rupture (SEGR) are not known precisely. SEGR is expected to occur when the energy deposition due to a heavy ion strike exceeds a certain threshold simultaneously with sufficient electric field across the gate dielectric. Typically the energy deposition is described by using the linear energy transfer (LET) of the given ion. Previously the LET has been demonstrated not to describe the SEGR sufficiently. The work presented here introduces a semi-empirical model for the SEGR prediction based on statistical variations in the energy deposition which are described theoretically.

Nuclear and High Energy PhysicsEngineeringWork (thermodynamics)ta114business.industryGate dielectricLinear energy transferMechanicsIonNuclear Energy and EngineeringElectric fieldDeposition (phase transition)Electrical and Electronic EngineeringbusinessEvent (particle physics)Energy (signal processing)SimulationIEEE Transactions on Nuclear Science
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Statistical Analysis of Heavy-Ion Induced Gate Rupture in Power MOSFETs—Methodology for Radiation Hardness Assurance

2012

A methodology for power MOSFET radiation hardness assurance is proposed. It is based on the statistical analysis of destructive events, such as gate oxide rupture. Examples of failure rate calculations are performed.

Nuclear and High Energy PhysicsSpace technologyMaterials scienceta114Dielectric strengthbusiness.industryElectrical engineeringFailure rateHardware_PERFORMANCEANDRELIABILITYlaw.inventionCapacitorNuclear Energy and EngineeringlawGate oxideMOSFETHardware_INTEGRATEDCIRCUITSOptoelectronicsElectrical and Electronic EngineeringPower MOSFETbusinessRadiation hardeningHardware_LOGICDESIGNIEEE Transactions on Nuclear Science
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SEGR in SiO<inf>2</inf>-Si<inf>3</inf>N<inf>4</inf> stacks

2013

Materials sciencebusiness.industryElectronic engineeringOptoelectronicsbusiness2013 14th European Conference on Radiation and Its Effects on Components and Systems (RADECS)
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Microbeam SEE Analysis of MIM Capacitors for GaN Amplifiers

2018

Broad-beam and microbeam single-event effect tests were performed on metal–insulator–metal capacitors with three different thicknesses of silicon nitride (Si3N4) dielectric insulator: 250, 500, and 750 nm. The broad-beam tests indicated that the devices with the thicker, 500- and 750-nm dielectric did not have a greater breakdown voltage. The surrounding structures of the capacitor were suspected to be a possible cause. Microbeam techniques made it possible to localize the failure location for the 500- and 750-nm devices. The failure occurs in the air bridge structure connected to the top capacitor plate, which can therefore be considered as an edge effect, while for the 250-nm devices, the…

Nuclear and High Energy PhysicsMaterials scienceInsulator (electricity)Dielectrickondensaattorit01 natural sciencesmetal–insulator–semiconductor (MIS) deviceslaw.inventionelektroniikkakomponentitchemistry.chemical_compoundlaw0103 physical sciencesBreakdown voltageElectrical and Electronic EngineeringMetal–insulator–metal (MIM) devicessingle event effects (SEEs)ta114ta213010308 nuclear & particles physicsbusiness.industryAmplifierMicrobeamsingle event gate ruptureCapacitorNuclear Energy and EngineeringSilicon nitridechemistrysäteilyfysiikkaElectrodeOptoelectronicsbusinessIEEE Transactions on Nuclear Science
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SEGR in SiO${}_2$–Si$_3$N$_4$ Stacks

2014

Abstract. This work presents experimental Single Event Gate Rupture (SEGR) data for Metal–Insulator–Semiconductor (MIS) devices, where the gate dielectrics are made of stacked SiO2–Si3N4 structures. A semi-empirical model for predicting the critical gate voltage in these structures under heavy-ion exposure is first proposed. Then interrelationship between SEGR cross- section and heavy-ion induced energy deposition probability in thin dielectric layers is discussed. Qualitative connection between the energy deposition in the dielectric and the SEGR is proposed. peerReviewed

PhysicsNuclear and High Energy Physicsta114Condensed matter physicsbusiness.industrymodelingDielectricMOSGate voltageSingle Event Gate Rupture (SEGR)Nuclear Energy and EngineeringOptoelectronicsElectrical and Electronic Engineeringbusinesssemi-empiricalDeposition (law)IEEE Transactions on Nuclear Science
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Influence of beam conditions and energy for SEE testing

2012

GANIL/Applications industrielles; The effects of heavy-ion test conditions and beam energy on device response are investigated. These effects are illustrated with two types of test vehicles: SRAMs and power MOSFETs. In addition, GEANT4 simulations have also been performed to better understand the results. Testing to high fluence levels is required to detect rare events. This increases the probability of nuclear interactions. This is typically the case for power MOSFETs, which are tested at high fluences for single event burnout or gate rupture detection, and for single-event-upset (SEU) measurement in SRAMs below the direct ionization threshold. Differences between various test conditions (…

Nuclear and High Energy PhysicsMaterials scienceIon beamPopulationchemistry.chemical_elementPower MOSFETsIonOpticsXenonIonizationion beam energyStatic random-access memoryElectrical and Electronic Engineeringspecie effectPower MOSFETeducationShadow mappingPhysicseducation.field_of_studyRange (particle radiation)power MOSFETta114business.industrySRAMNuclear Energy and EngineeringOrders of magnitude (time)chemistry[PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci]Atomic physicsspecies effectSRAM.businessBeam (structure)Energy (signal processing)Voltage2011 12th European Conference on Radiation and Its Effects on Components and Systems
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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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