Superconductor to resistive state switching by multiple fluctuation events in NbTiN nanostrips

Ejrnæs, M.; Salvoni, Daniela; Parlato, L.; Massarotti, Davide; Caruso, Roberta; Tafuri, F.; Xiao-yan, Yang; You, Lixing; Wang, Z.; Pepe, Giovanni Piero; Cristiano, R.

doi:10.1038/s41598-019-42736-3

Cited by 31 publications

(31 citation statements)

References 33 publications

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“…Phase slip events, indeed, reflect into the value of the switching current (I S ), that is, when the bias current is swept from zero to above the critical current, the bias value at which the superconductor switches to the normal state. Due to the stochastic nature of phase slip events, I S statistically spreads around I C , and its distribution [also known as the switching current probability distribution (SCPD)] naturally provides information on the phase slips dynamics of mesoscopic superconducting devices [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26] under the influence of external parameters such as, for instance, the temperature or an externally applied electric field. The latter was recently investigated in hybrid graphene-based Josephson junctions [27,28], but no relationship between the electric field and the SCPDs has been observed so far in genuine all-metallic superconducting systems.…”

mentioning

confidence: 99%

Electrostatic control of phase slips in Ti Josephson nanotransistors

Puglia,

De Simoni,

Giazotto

2019

Preprint

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mentioning

confidence: 99%

Electrostatic control of phase slips in Ti Josephson nanotransistors

Puglia,

De Simoni,

Giazotto

2019

Preprint

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“…First, the different phase slip regimes were identified thanks to the evolution of distribution standard deviation

as a function of T . The Figure 7 insets show the expected behavior of the

vs. T curve in the three different phase slips regimes, which is flat at low temperatures in the Quantum Phase Slip (QPS) regime [ 50 , 51 , 52 ], linear as a function of the temperature T in the Thermal Activated Phase Slip (TAPS) regime [ 53 ], and decreasing for the Multiple Phase Slip (MPS) regime as T increases [ 45 , 46 , 47 , 49 , 54 , 55 , 56 , 57 ]. The temperature

, separating the QPS and the TAPS regime, occurs at about

mK, while the crossover between TAPS and MPS regimes appears for

mK.…”

Section: Nonthermal Origin Of Supercurrent Suppression In Gated Almentioning

confidence: 99%

Gate Control of Superconductivity in Mesoscopic All-Metallic Devices

Puglia

Simoni²,

Giazotto³

2021

Materials

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The possibility to tune, through the application of a control gate voltage, the superconducting properties of mesoscopic devices based on Bardeen–Cooper–Schrieffer metals was recently demonstrated. Despite the extensive experimental evidence obtained on different materials and geometries, a description of the microscopic mechanism at the basis of such an unconventional effect has not been provided yet. This work discusses the technological potential of gate control of superconductivity in metallic superconductors and revises the experimental results, which provide information regarding a possible thermal origin of the effect: first, we review experiments performed on high-critical-temperature elemental superconductors (niobium and vanadium) and show how devices based on these materials can be exploited to realize basic electronic tools, such as a half-wave rectifier. Second, we discuss the origin of the gating effect by showing gate-driven suppression of the supercurrent in a suspended titanium wire and by providing a comparison between thermal and electric switching current probability distributions. Furthermore, we discuss the cold field-emission of electrons from the gate employing finite element simulations and compare the results with experimental data. In our view, the presented data provide a strong indication regarding the unlikelihood of the thermal origin of the gating effect.

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“…• for higher temperatures, T > T M , the phase slips events occur more than one at once, and the system shows the multiple phase slip (MPS) regime [31]. In contrast to QPS and TAPS, there are no analytical models for MPS.…”

Section: Rcsj Model For Phase Slips In Superconducting Weak-linksmentioning

confidence: 99%

Phase slips dynamics in gated Ti and V all-metallic supercurrent nano-transistors: a review

Puglia,

De Simoni,

Giazotto

2021

Preprint

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The effect of electrostatic gating on metallic elemental superconductors was recently demonstrated in terms of modulation of the switching current and control of the current phase relation in superconducting quantum interferometers. The latter suggests the existence of a direct connection between the macroscopic quantum phase (φ) in a superconductor and the applied gate voltage. The measurement of the switching current cumulative probability distributions (SCCPD) is a convenient and powerful tool to analyze such relation. In particular, the comparison between the conventional Kurkijärvi-Fulton-Dunkleberger model and the gate-driven distributions give useful insights into the microscopic origin of the gating effect. In this review, we summarize the main results obtained in the analysis of the phase slip events in elemental gated superconducting weak-links in a wide range of temperatures between 20 mK and 3.5 K. Such a large temperature range demonstrates both that the gating effect is robust as the temperature increases, and that fluctuations induced by the electric field are not negligible in a wide temperature range.

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Superconductor to resistive state switching by multiple fluctuation events in NbTiN nanostrips

Cited by 31 publications

References 33 publications

Electrostatic control of phase slips in Ti Josephson nanotransistors

Electrostatic control of phase slips in Ti Josephson nanotransistors

Gate Control of Superconductivity in Mesoscopic All-Metallic Devices

Phase slips dynamics in gated Ti and V all-metallic supercurrent nano-transistors: a review

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