Litcius/Paper detail

Physical Model of Low-Temperature to Cryogenic Threshold Voltage in MOSFETs

Arnout Beckers, Farzan Jazaeri, Alexander Grill, N. Subramanian, Bertrand Parvais, Christian Enz

2020IEEE Journal of the Electron Devices Society108 citationsDOIOpen Access PDF

Abstract

This article presents a physical model of the threshold voltage in MOSFETs valid down to 4.2 K. Interface traps close to the band edge modify the saturating temperature behavior of the threshold voltage observed in cryogenic measurements. Dopant freezeout, bandgap widening, and uniformly distributed traps in the bandgap do not change the qualitative behavior of the threshold voltage over temperature. Care should be taken because dopant freezeout results in a different physical definition of the threshold voltage. Using different definitions changes significantly the threshold current level. The proposed model is experimentally validated with measurements in large-area nMOS and pMOS devices of a commercial 28-nm bulk CMOS process down to 4.2 K. Our modeling results suggest that a pMOS-specific phenomenon in the gate stack is responsible for the non-saturating temperature behavior of the threshold voltage in pMOS devices.

Topics & Concepts

PMOS logicThreshold voltageNMOS logicMaterials scienceDopantOptoelectronicsMOSFETNegative-bias temperature instabilityVoltageCMOSDrain-induced barrier loweringWide-bandgap semiconductorCondensed matter physicsElectrical engineeringDopingPhysicsTransistorEngineeringAdvancements in Semiconductor Devices and Circuit DesignSemiconductor materials and devicesElectrostatic Discharge in Electronics