Showing posts with label InGaAs. Show all posts
Showing posts with label InGaAs. Show all posts

Mar 8, 2023

[paper] Cryogenic Characteristics of InGaAs MOSFET

L. Södergren, P. Olausson and E. Lind
Cryogenic Characteristics of InGaAs MOSFET
in IEEE TED, vol. 70, no. 3, pp. 1226-1230, March 2023,
DOI: 10.1109/TED.2023.3238382

Abstract: We present an investigation of the temperature dependence of the current characteristic of a long-channel InGaAs quantum well MOSFET. A model is developed, which includes the effects of band tail states, electron concentration-dependent mobility, and interface trap density to accurately explain the measured data over all modes of operation. The increased effect of remote impurity scattering is associated with mobility degradation in the subthreshold region. The device has been characterized down to 13 K, with a minimum inverse subthreshold slope of 8 mV/dec and a maximum ON-state mobility of 6700 cm2/Vs and with values of 75 mV/dec and 3000 cm2/Vs at room temperature.

FIG: Measured transfer characteristics at 13, 100, and 300 K together with the fit model with
(a) VDS=50 mV and (b) VDS=500 mV.






Jul 29, 2020

[paper] Vertical III-V Nanowire MOSFETs on Si

Olli-Pekka Kilpi, Markus Hellenbrand, Johannes Svensson, Axel R. Persson, Reine Wallenberg, Erik Lind, Member, IEEE, and Lars-Erik Wernersson
High-Performance Vertical III-V Nanowire MOSFETs on Si With gm > 3 mS/μm
in IEEE EDL vol. 41, no. 8, pp. 1161-1164, Aug. 2020
DOI: 10.1109/LED.2020.3004716

Abstract: Vertical III-V nanowire MOSFETs have demonstrated excellent performance including high transconductance and high Ion. One main bottleneck for the vertical MOSFETs is the large access resistance arising from the contacts and ungated regions. We demonstrate a process to reduce the access resistance by combining a gate-last process with ALD gate-metal deposition. The devices demonstrate fully scalable gm down to Lg = 25 nm. These vertical core/shell InAs/InGaAs MOSFETs demonstrate gm = 3.1 mS/μm and Ron = 190 μm. This is the highest gm demonstrated on Si. Transmission line measurement verifies a low contact resistance with RC = 115 μm, demonstrating that most of the MOSFET access resistance is located in the contact regions.
FIG: (a) of the MOSFET structure demonstrating benefit of the TiN gate metal;
(b )output characteristics of the vertical nanowire MOSFET 
with 90 nanowires, LG = 25 nm and diameter 17 nm.

Acknowledgment: This work was supported in part by the Swedish Research Council, in part by the Knut and Alice Wallenberg Foundation, in part by the Swedish Foundation for Strategic Research, and in part by the European Union H2020 Program INSIGHT under Grant 688784.