28-nm FDSOI nMOSFET RF Figures of Merits and Parasitic Elements Extraction at Cryogenic Temperature Down to 77 K

Esfeh, Babak Kazemi; Kilchytska, Valeriya; Planes, N.; Haond, M.; Flandre, Denis; Raskin, Jean‐Pierre

doi:10.1109/jeds.2019.2906724

Cited by 13 publications

(9 citation statements)

References 14 publications

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“…The present paper extends our previous work [18]. It is the continuation of our previous study [17] on the RF performances of 28-nm FD-SOI transistors down to 4.2 K, the liquid-helium temperature. The paper is organized as follow.…”

Section: Introductionsupporting

confidence: 80%

“…The influence of cryogenic temperature on 28-nm bulk and FD-SOI CMOS technologies with a main focus on analog parameters and modeling has been discussed in [7] and [9]. In [16] and [17], the above studies were completed by investigating the analog and RF figures of merit (FoMs) in 28nm FD-SOI CMOS technology at temperatures down to 77 K. A strong improvement of both analog and RF FoMs was demonstrated [16], [17].…”

Section: Introductionmentioning

confidence: 99%

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28-nm FD-SOI CMOS RF Figures of Merit Down to 4.2 K

Nyssens

Halder

Esfeh

et al. 2020

IEEE J. Electron Devices Soc.

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This work presents a detailed RF characterization of 28-nm FD-SOI nMOSFETs at cryogenic temperatures down to 4.2 K. Two main RF Figures of Merit (FoMs), i.e. current-gain cutoff frequency (ft) and maximum oscillation frequency (fmax), as well as parasitic elements of the small-signal equivalent circuit, are extracted from the measured S-parameters. An improvement of up to ~130 GHz in ft and ~75 GHz in fmax is observed for the shortest device (25 nm) at low temperature. The behavior of RF FoMs versus temperature is discussed in terms of small-signal equivalent circuit elements, both intrinsic and extrinsic (parasitics). This study suggests 28-nm FD-SOI nMOSFETs as a good candidate for future cryogenic applications down to 4.2 K and clarifies the origin and limitations of the performance.

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Section: Introductionsupporting

confidence: 80%

Section: Introductionmentioning

confidence: 99%

28-nm FD-SOI CMOS RF Figures of Merit Down to 4.2 K

Nyssens

Halder

Esfeh

et al. 2020

IEEE J. Electron Devices Soc.

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“…The impact of Coulomb scattering on the mobility is more important in shorter channels [23]. The small reduction in gm from 100 K to 77 K was already reported in [10], [12] and explained by a mobility saturating at 100 K and slightly deteriorating at 77 K due to a dominant Coulomb scattering effect.…”

Section: Impact Of Self-heating On Analog Figures Of Meritsupporting

confidence: 51%

“…With temperature reduction from 300 K to 77 K, the gm improvement of 30 % is larger than the gd degradation of only 12 %, resulting in an overall improvement of Av by about 15% at a fixed bias condition of Vg = Vd = 1 V. The transconductance variation with temperature is mainly related to the mobility dependence on temperature. As temperature decreases, two concurrent mechanisms dictate the mobility behavior: (i) Coulomb scattering (featuring a mobility reduction with decreasing temperature) on the defects of the source/drain and extensions regions and (ii) phonon scattering (featuring a mobility improvement with decreasing temperature) [10], [12]. The impact of Coulomb scattering on the mobility is more important in shorter channels [23].…”

Section: Impact Of Self-heating On Analog Figures Of Meritmentioning

confidence: 99%

“…Outstanding electrostatic and variability control, excellent performance in terms of low-power, high-speed, as well as attractive analog and RF figures of merit (FoMs) offered by this technology were demonstrated in numerous publications [1]- [8]. This technology was also largely investigated at cryogenic temperatures showing promising improvement of device performance [9]- [12]. Apart from space applications, cryogenic studies are nowadays strongly motivated by a breakthrough in silicon-based quantum bits (qubit) which requires their co-integration with the control blocks and readout electronics for the realization of quantum computers [13]- [16].…”

Section: Introductionmentioning

confidence: 99%

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Self-Heating in FDSOI UTBB MOSFETs at Cryogenic Temperatures and its Effect on Analog Figures of Merit

Nyssens

Halder

Esfeh

et al. 2020

IEEE J. Electron Devices Soc.

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This work studies the self-heating (SH) effect in ultra-thin body ultra-thin buried oxide (UTBB) FDSOI MOSFETs at cryogenic temperatures down to 77 K. S-parameter measurements in a wide frequency range, with the so-called RF technique, are employed to assess SH parameters and related variation of analog figures of merit (FoMs) at different temperatures. Contrary to the expectations, the effect of self-heating on analog FoMs is slightly weaker at cryogenic temperatures with respect to roomtemperature case. The extracted thermal resistance and channel temperature rise at 300 K and 77 K in short-channel devices are of the same order of magnitude. The observed increase in SH characteristic frequency with temperature reduction emphasizes the advantage of the RF technique for the fair analysis of SH-related features in advanced technologies at cryogenic temperatures.

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Low-power transimpedance amplifier for cryogenic integration with quantum devices

Guevel

Billiot

Paz

et al. 2020

Applied Physics Reviews

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The development of quantum electronic devices operating below a few Kelvin degrees is raising the demand for cryogenic complementary metal-oxide-semiconductor electronics (CMOS) to be used as in situ classical control/readout circuitry. Having a minimal spatial separation between quantum and classical hardware is necessary to limit the electrical wiring to room temperature and the associated heat load and parasitic capacitances. Here, we report prototypical demonstrations of hybrid circuits combining silicon quantum dot devices and a classical transimpedance amplifier, which is characterized and then used to measure the current through the quantum dots. The two devices are positioned next to each other at 4.2 K to assess the use of the cryogenic transimpedance amplifier with respect to a room-temperature transimpedance amplifier. A quantum device built on the same substrate as the transimpedance amplifier is characterized down to 10 mK. The transimpedance amplifier is based on commercial 28 nm fully depleted Silicon-on-insulator (FDSOI) CMOS. It consists of a two-stage Miller-compensated operational amplifier with a 10 MΩ polysilicon feedback resistor, yielding a gain of 1.1×107 V/A. We show that the transimpedance amplifier operates at 10 mK with only 1 μW of power consumption, low enough to prevent heating. It exhibits linear response up to ±40 nA and a measurement bandwidth of 2.6 kHz, which could be extended to about 200 kHz by design optimization. The realization of custom-made electronics in FDSOI technology for cryogenic operation at any temperature will improve measurement speed and quality inside cryostats with higher bandwidth, lower noise, and higher signal-to-noise ratio.

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28-nm FDSOI nMOSFET RF Figures of Merits and Parasitic Elements Extraction at Cryogenic Temperature Down to 77 K

Cited by 13 publications

References 14 publications

28-nm FD-SOI CMOS RF Figures of Merit Down to 4.2 K

28-nm FD-SOI CMOS RF Figures of Merit Down to 4.2 K

Self-Heating in FDSOI UTBB MOSFETs at Cryogenic Temperatures and its Effect on Analog Figures of Merit

Low-power transimpedance amplifier for cryogenic integration with quantum devices

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