Your search keyword '"Rzepa, G."' showing total 3 results

1. NBTI Degradation and Recovery in Analog Circuits: Accurate and Efficient Circuit-Level Modeling.

Author

Giering, K.-U., Puschkarsky, K., Reisinger, H., Rzepa, G., Rott, G., Vollertsen, R., Grasser, T., and Jancke, R.

Subjects

METAL oxide semiconductor field-effect transistors, ELECTRONIC circuit design, TEMPERATURE measurements, ELECTRIC potential, LOGIC circuits

Abstract

We investigate the negative-bias temperature instability (NBTI) degradation and recovery of pMOSFETs under continuously varying analog-circuit stress voltages and thereby generalize existing digital-stress NBTI studies. Starting from our ultrafast NBTI measurements and an extensive TCAD analysis, we study two physics-based compact models for analog-stress NBTI including recovery. The high accuracy of both models is evidenced from single-FET analog-stress and circuit-level ring oscillator experiments. Their numerical efficiency allows direct coupling to circuit simulators and permits to accurately account for NBTI already during circuit design. Furthermore, one of the models calculates the time-dependent NBTI variability of single-FET and of circuit performance parameters. We demonstrate our NBTI models on a ring oscillator and calculate the mean drift and statistical distribution of its oscillation frequency. [ABSTRACT FROM AUTHOR]

Published

2019

2. Superior NBTI in High- $k$ SiGe Transistors?Part I: Experimental.

Author

Waltl, M., Rzepa, G., Grill, A., Goes, W., Franco, J., Kaczer, B., Witters, L., Mitard, J., Horiguchi, N., and Grasser, T.

Subjects

*TRANSISTOR design & construction, *TEMPERATURE control of electronics, *METAL oxide semiconductor field-effect transistors, *SILICON industry, *PERFORMANCE of transistors, *EQUIPMENT & supplies

Abstract

SiGe quantum-well pMOSFETs have recently been introduced for enhanced performance of transistors. Quite surprisingly, a significant reduction in negative bias temperature instability (NBTI) was also found in these devices. Furthermore, a stronger oxide field acceleration of the degradation in SiGe devices compared with Si devices was reported. These observations were speculated to be a consequence of the energetical realignment of the SiGe channel with respect to the dielectric stack. As these observations were made on large-area devices, only the average contribution of many defects to NBTI could be studied. In order to reveal the microscopic reasons responsible for the improved reliability, a detailed study of single defects is performed in nanoscale devices. To provide a detailed picture of single charge trapping, the step-height distributions for different device variants are measured and found to follow a unimodal and bimodal distribution. This finding suggests two conducting channels, one in the SiGe and one in the thin Si cap layer. We, furthermore, demonstrate that similar trap depth distributions are present among the device variants supported by a similar stress bias dependence of the capture times of the identified single defects. We conclude that NBTI is primarily determined by the dielectric stack and not by the device technology. [ABSTRACT FROM AUTHOR]

Published

2017

3. Superior NBTI in High-k SiGe Transistors–Part II: Theory.

Author

Waltl, M., Rzepa, G., Grill, A., Goes, W., Franco, J., Kaczer, B., Witters, L., Mitard, J., Horiguchi, N., and Grasser, T.

Subjects

*CAVITY polaritons, *MOS integrated circuits, *SILICON, *FIELD-effect transistors, *THRESHOLD voltage

Abstract

The susceptibility of conventional silicon p-channel MOS transistors to negative bias temperature instabilities (NBTIs) is a serious threat to further device scaling. One possible solution to this problem is the use of a SiGe quantum-well channel. The introduction of a SiGe layer, which is separated from the insulator by a thin Si cap layer, not only results in high mobilities but also superior reliability with respect to NBTI. In part one of this paper, we provide experimental evidence for reduced NBTI by thoroughly studying single traps in nanoscale devices. In this paper, we present detailed TCAD simulations and employ the four-state nonradiative multiphonon model to determine the energetical and spatial positions of the identified single traps. The found trap levels agree with the defect bands estimated in large-area devices. Our conclusions are also supported by the observation of similar activation energies for defects present in transistors of various device geometries. From the calibrated TCAD simulations data, an impressive boost of the time-to-failure for the SiGe transistor can be predicted and explained. [ABSTRACT FROM AUTHOR]

Published

2017