At IRPS 2026,—one of the leading events for cutting-edge research in microelectronics reliability—CEA-Leti will showcase seven papers highlighting its wide-ranging expertise. These span areas such as device physics, process integration, RF technologies, FD-SOI, GaN, BEOL reliability, and low-temperature approaches that support 3D sequential integration. In addition, its researchers have contributed to two more collaborative projects featured at the event.
The work underscores CEA-Leti’s strength in combining advanced characterization techniques with physics-based modeling to deliver early insights into reliability. These findings help both technology developers and circuit designers create more robust, industry-ready solutions.
Olivier Faynot, director of CEA-Leti’s Silicon Components Department and IEEE Fellow, noted that the presentations demonstrate the institute’s comprehensive capabilities—from low-temperature integration and advanced materials analysis to modeling and design-level mitigation. He added that by improving understanding of degradation mechanisms and circuit constraints, their research helps speed up the industrial adoption of GaN, FD-SOI, and 3D sequential technologies.
Presentations
Radio Frequency (Alexis Divay from CEA-Leti will chair the RF/mmW/5G session)
“RF Aging Extensive Characterization & Modeling for Reliability‑Aware Power Amplifier Design”
Thursday, March 26, 1:35‑2:00 PM
Authors: Tarek Daher, Alexis Divay in collaboration with STMicroelectronics
A novel methodology directly measures hot‑carrier‑induced (HCI) lifetime of standalone SOI power amplifiers under realistic RF stress, covering varied bias conditions and load‑impedance mismatches. Empirical time‑to‑failure contour maps are generated, giving designers immediate visibility into performance‑reliability trade‑offs during early PA design for emerging mmWave 5G and beyond‑5G applications.
“Thermal Robustness of a CMOS‑Compatible GaN‑on‑Si MIS‑HEMT Technology”
Thursday, March 26, 3:25‑3:50 PM
Author: Luca Nyssens
1,400 h, up‑to‑375 °C unbiased storage tests on 0.15 µm SiN/InAlN/GaN MIS‑HEMTs (CMOS‑compatible) show only modest Vth shift (≈‑200 mV), ~20 % contact‑resistance rise, and small drops in Id and gm. Microscopy confirms no side‑wall interdiffusion thanks to a refractory alloy gate. The devices remain electrically stable at extreme temperatures, proving GaN power blocks can be monolithically integrated on silicon for high‑temperature automotive or aerospace electronics.
3D Sequential Integration & Low Temperature Technologies
“Reaching the BTI 10‑Year Lifetime for 2.5 V BEOL‑Compatible (< 420 °C) High‑Voltage Si‑CMOS”
Tuesday, March 24, 3:40‑4:05 PM
Author: William Vandendaele
Using a Si‑poly gate, UV‑nanosecond laser anneal, and high‑pressure passivation, 2.5 V BEOL‑compatible transistors achieve the 10‑year BTI target despite the low‑temperature budget. TiN gates fail due to oxygen scavenging. Designers now have a proven low‑temp flow for >2.5‑rated CMOS that can be stacked in 3D sequential processes without exceeding 420 °C.
“Influence of Channel Doping on HCI Degradation in Analog SOI nMOSFETs”
Tuesday, March 24, 4:30‑4:55 PM
Author: Abygaël Viey
TCAD simulations and experimental validation show that lower channel doping expands the impact‑ionization region, increasing hot‑carrier generation and interface‑trap formation in nitrided SiO₂‑gate SOI nMOSFETs. Incorporating the channel implantation dose into the Takeda model accurately predicts the observed rise in time‑to‑failure, providing a clear path for analog designers to mitigate HCI by tailoring doping profiles.
“Improving Electromigration Lifetime Through Power‑Grid Segmentation: An Experimental Study”
Thursday, March 26, 2:00‑2:25 PM
Authors: Robert Bloom (University of Minnesota) with contribution from Stéphane Moreau (CEA-Leti)
Silicon‑level EM tests on segmented power‑grid structures exploit the Blech effect: shorter segments reduce stress‑migration‑driven void formation, yielding markedly longer time‑to‑failure and smaller IR‑drop shifts. Segmenting BEOL power grids becomes a practical, layout‑level knob to boost EM robustness in advanced nodes carrying high currents.
“Ground-Plane Effect on Random Telegraph Noise in Mesa-Isolated SOI MOSFETs for 3D Sequential CISi”
Tuesday, March 24, 11:20‑11:45 PM
Authors: Ahmed Machmach (STMicroelectronics) with contribution from Joris Lacord and Fabienne Ponthenier (CEA-Leti)
Increasing the substrate (ground‑plane) bias reshapes the channel’s electric field, pushing more oxide‑trap events above the detection threshold and amplifying their current spikes. This controllable RTN boost helps designers predict and mitigate noise in 3‑D sequential CMOS image sensors.
“Dit-Nt Correlation in pBTI Stressed SOI nMOSFET via Low Frequency Noise Measurements”
Tuesday, March 24, 2:00-2:25 PM
Author: Antoine Albouy
Low‑frequency‑noise measurements show that as pBTI stress progresses, oxide‑trap density (Nt) rises in lockstep with interface‑trap density (Dit). The tight correlation indicates that interface quality dominates stress‑induced noise, emphasizing the need for robust interface engineering in future FD‑SOI devices.
FD-SOI
“Spacer Trapping Effect on Hot‑Carrier Degradation Dynamics for Advanced FD‑SOI Nodes”
Wednesday, March 25, 2:00‑2:25 PM
Author: Tadeu Mota Frutuoso
Comparing high‑ vs. low‑trapping SiCO spacers reveals that trapped charge in spacers dominates early HCI wear but saturates quickly; low‑trapping spacers completely suppress this early degradation. Spacer material selection is a decisive lever for extending device lifetime in forthcoming GAA and CFET platforms.
“Modeling the Impact of HK Thickness Scaling (Down to 1.1 nm) on Gate Leakage and PBTI in Advanced FD‑SOI Devices”
Tuesday, March 24, 4:05‑4:30 PM
Author: Elhadji Alhousseyni Diallo
Using direct‑tunnelling physics and Comphy simulations, this study quantifies how ultra‑thin high‑k (HK) layers affect gate leakage and positive‑bias‑temperature‑instability (PBTI). A higher tunnel mass in sub‑2 nm oxides indicates a microstructural shift, while reduced HK thickness simultaneously lowers leakage and improves PBTI endurance. The results provide a calibrated model that designers can employ when pushing HK scaling for next‑generation FD‑SOI technologies.
This work was supported by NexGen 2030, FAMES Pilot Line and IRT Nanoelec.
