Microwave Admittance of Gold‐Palladium Nanowires with Proximity‐Induced Superconductivity

Lake, Russell; Govenius, Joonas; Kokkoniemi, Roope; Tan, Kuan Yen; Partanen, Matti; Virtanen, Pauli; Möttönen, Mikko

doi:10.1002/aelm.201600227

Cited by 10 publications

(7 citation statements)

References 46 publications

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“…A similar technique based on single mode resonators was already used for the investigation of short Josephson junctions embedded in superconducting rings [35][36][37]. More related to the present work, the impedance of an array of SNS dc SQUIDS was measured using a superconducting multimode resonator [38]. This work focused on the temperature dependence of the effective inductive and resistive components of the SNS SQUIDs whereas our work focuses instead of the phase dependence which bares most of the signature of the dynamics of Andreev states [14,16].…”

Section: Methodsmentioning

confidence: 99%

Coherence-enhanced phase-dependent dissipation in long SNS Josephson junctions: Revealing Andreev bound state dynamics

Dassonneville¹,

Murani²,

Ferrier³

et al. 2018

Phys. Rev. B

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One of the best known causes of dissipation in ac driven quantum systems stems from photon absorption causing transitions between levels. Dissipation can also be caused by the retarded response to the time-dependent excitation, and in general gives insight into the system's relaxation times and mechanisms. Here we address the dissipation in a mesoscopic normal wire with superconducting contacts, that sustains a dissipationless supercurrent at zero frequency and that may therefore naively be expected to remain dissipationless at frequency lower than the superconducting gap. We probe the high frequency linear response of such a Normal/Superconductor (NS) ring to a time-dependent flux by coupling it to a highly sensitive multimode microwave resonator. Far from being the simple, dissipationless, derivative of the supercurrent-versus-phase relation, the ring's ac susceptibility also displays a dissipative component whose phase dependence is a signature of the dynamical processes occurring within the Andreev spectrum. We show how dissipation is driven by the competition between two mechanisms. The first is the relaxation of the Andreev levels distribution function, while the second correspond to microwave-induced transitions within the spectrum. Depending on the relative strength of those contributions, dissipation can be maximal at π , a phase at which the proximity-induced minigap closes, or can be maximal near π/2, a phase at which the dc supercurrent is maximal. We also find that the dissipative response paradoxically increases at low temperature and can even exceed the normal state conductance. The results are successfully confronted with theoretical predictions of the Kubo linear response and time-dependent Usadel equations, derived from the Bogoliubov-de Gennes Hamiltonian describing the SNS junction. These experiments thus demonstrate the power of the ac susceptibility measurement of individual hybrid mesoscopic systems in probing in a controlled way the quantum dynamics of Andreev bound states. By spanning different physical regimes, our experiments provide a unique access to inelastic scattering and spectroscopy of an isolated quantum coherent system, and reveal the associated relaxation times. This technique should be a tool of choice to investigate topological superconductivity and detect the topological protection of edge states.

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Section: Methodsmentioning

confidence: 99%

Coherence-enhanced phase-dependent dissipation in long SNS Josephson junctions: Revealing Andreev bound state dynamics

Dassonneville¹,

Murani²,

Ferrier³

et al. 2018

Phys. Rev. B

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“…2(b). We encounter no phase jumps and relate the external phase ϕ ext = n odd π (= n even π) to points of minimal (maximal) resonance frequencies [10,14]. Besides f 0 , the resonance lineshape also changes as seen in Fig.…”

Section: Reflectomertymentioning

confidence: 84%

“…8(a) one can verify this relation, since the relation between the experimentally deduced values of the susceptance B J and conductance G s obtained at ϕ = π for all different V bg -clearly follows a linear trend. Furthermore, the ratio B J /G s is the inverse loss tangent describing the quality of the Josephson inductance [14], where a larger ratio implies a more ideal behavior of the inductance. We attribute the cone-shaped spread in Fig.…”

Section: Comparison With Theorymentioning

confidence: 99%

“…The junction admittance can be probed as a function of phase by embedding a JJ in an rf SQUID that couples to a resonator [9][10][11][12][13]. The rf SQUID acts as a magnetic flux-tunable complex impedance in the circuit that shifts and broadens the resonate behavior, from which one can infer the phase-dependent inductive and dissipative response of the junction [14]. The strong demand for in-situ controllable junctions in microwave applications has raised the attention to JJs consisting of gate-tunable weak links [15].…”

Section: Introductionmentioning

confidence: 99%

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Phase-dependent microwave response of a graphene Josephson junction

Haller,

Fülöp,

Indolese

et al. 2021

Preprint

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Gate-tunable Josephson junctions embedded in a microwave environment provide a promising platform to in-situ engineer and optimize novel superconducting quantum circuits. The key quantity for the circuit design is the phase-dependent complex admittance of the junction, which can be probed by sensing an rf SQUID with a tank circuit. Here, we investigate a graphene-based Josephson junction as a prototype gate-tunable element enclosed in a SQUID loop that is inductively coupled to a superconducting resonator operating at 3 GHz. With a concise circuit model that describes the dispersive and dissipative response of the coupled system, we extract the phase-dependent junction admittance corrected for self-screening of the SQUID loop. We decompose the admittance into the current-phase relation and the phase-dependent loss and as these quantities are dictated by the spectrum and population dynamics of the supercurrent-carrying Andreev bound states, we gain insight to the underlying microscopic transport mechanisms in the junction. We theoretically reproduce the experimental results by considering a short, diffusive junction model that takes into account the interaction between the Andreev spectrum and the electromagnetic environment, from which we deduce a lifetime of ∼ 17 ps for non-equilibrium populations.

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“…Accurate determination of S-parameters in a cryogenic environment has wide applicability to the development of active and passive cryo-electronic devices with immediate impact on filtering 12 , interconnects 13 , multiplexers 14 , non-reciprocal devices 15 , single-flux-quantum-based technologies 16,17 , cryo-CMOS technologies 18 , quantum hardware packaging [19][20][21] , microwave impedance and waveform metrology 22 , and parametric amplifier development [23][24][25][26][27] , among others. Beyond quantum computing, scientific applications requiring accurate S-parameter characterization at low temperature include astrophysical observations 28 and high-frequency electronic transport experiments [29][30][31][32] .…”

mentioning

confidence: 99%

Microwave calibration of qubit drive line components at millikelvin temperatures

Simbierowicz,

Monarkha,

Singh

et al. 2021

Preprint

Self Cite

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Microwave Admittance of Gold‐Palladium Nanowires with Proximity‐Induced Superconductivity

Cited by 10 publications

References 46 publications

Coherence-enhanced phase-dependent dissipation in long SNS Josephson junctions: Revealing Andreev bound state dynamics

Coherence-enhanced phase-dependent dissipation in long SNS Josephson junctions: Revealing Andreev bound state dynamics

Phase-dependent microwave response of a graphene Josephson junction

Microwave calibration of qubit drive line components at millikelvin temperatures

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