Self-heating assessment and cold current extraction in FDSOI MOSFETs

session: Modeling and CharacterizationInternational audienceWe present an experimental study of thermal effects in thin film FDSOI MOSFETs, with a focus on the impact of self-heating effect (SHE) on drain current. We have performed thermal resistance extraction using the gate thermometry method, and calculated the resulting cold drain current (Id0), i.e. without SHE. We demonstrate that SHE is more pronounced in shorter and narrower devices without essential differences between nMOS and pMOS transistors. Our experiments show that although the temperature increases significantly in the channel due to SHE, its effect on the ION performances could be limited at operating voltage

Self-Heating Effect in FDSOI Transistors Down to Cryogenic Operation at 4.2 K

International audienc

Performance and Reliability of a Fully Integrated 3D Sequential Technology

session T7: Process and Material TechnologyInternational audienceWe investigate in detail, for the first time, both performance and reliability of a 3D sequential integration process. It is clearly demonstrated that the top level transistor can be successfully processed at 630°C with almost no impact on the performance and reliability of the bottom level. It is also highlighted that top level devices meet the P&NBTI reliability requirements. Finally an example of successful and robust 3D logic integration is proposed based on a 3D inverter combining a top-level PMOS with a bottom-level NMOS

Thermal effects in 3D sequential technology

session 7: Characterization, Reliability, and Yield: Reliability of Advanced Devices (7.6)International audienceWe present for the first time an experimental study of thermal effects in 3D sequential integration, including Self-Heating Effect (SHE) and thermal coupling between the two levels of ultra-thin body FDSOI transistors. We extracted a large set of experimental data using different thermometry techniques, and different heater-sensor configurations allowed by this specific stacked integration. We described SHE in top and bottom transistor levels, as well as the influence of a transistor in ON state on a transistor stacked above or below. At the same time, we provide for the first time an experimental validation that the temperature increase given by gate resistance thermometry technique is equal to the temperature in the channel given by the subthreshold slope. Finally, this work can be also used to manage thermal effects for logic or analog applications, and help further optimization of 3D sequential integrated circuits through both technology and design solutions

Shaping circuit environment to face the thermal challenge Innovative technologies from low to high power electronics

International audienc