Detection of Weak Microwave Fields with an Underdamped Josephson Junction

Oelsner, G.; Andersen, Christian Kraglund; Rehák, M.; Schmelz, M.; Anders, S.; Grajcar, M.; Hübner, Uwe; Mølmer, Klaus; Il’ichev, E.

doi:10.1103/physrevapplied.7.014012

Cited by 56 publications

(40 citation statements)

References 41 publications

(39 reference statements)

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“…Therewith the resonator frequency will shift to lower values making the sensitivity frequency dependent. For even higher detunings already a value of 0.5 of sensitivity at a single photon level is achieved for the discussed device [36].…”

mentioning

confidence: 92%

Application and fabrication aspects of sub-micrometer-sized Josephson junctions

Oelsner

Hübner

Anders

et al. 2017

Low Temperature Physics

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We present two possible methods for the fabrication of sub-micron sized Josephson junctions, namely the shadow-evaporation technique and the cross-type technology. Their importance for the field of modern superconducting technology is discussed. As examples we present measurement results of a two-qubit sample and a prototype of a microwave detector fabricated each by one of the described methods. We review potential applications of superconducting quantum circuits based on the developed methods.

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confidence: 92%

Application and fabrication aspects of sub-micrometer-sized Josephson junctions

Oelsner

Hübner

Anders

et al. 2017

Low Temperature Physics

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“…There are, at least, two different approaches for practical realization of the single-photon detectors based on Josephson junctions, both having their advantages and disadvantages. The first approach relies on a continuous current sweep at a constant repetition rate and the measurements of the switching current distributions, from which the response and sensitivity can be determined [13][14][15]. In particular, in [15] the tunneling properties of the current-biased Josephson junction coupled with a resonator directly depend on the number of microwave photons in the resonator.…”

Section: Introductionmentioning

confidence: 99%

Microwave photon detection by an Al Josephson junction

Revin¹,

Pankratov²,

Gordeeva³

et al. 2020

Preprint

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The aluminum Josephson junction (JJ) with a critical current, suppressed by a factor of three comparing with the maximal value calculated from the gap, is experimentally investigated for application as a threshold detector of microwave photons. We present the preliminary results of measurements of the lifetime of the superconducting state and the probability of switching by 9 GHz external signal. We found an anomalously large lifetime, not described by the Kramers' theory for the escape time over a barrier under the influence of fluctuations. We explain it by the phase diffusion regime, which is evident from the temperature dependence of the switching current histograms. Therefore, the phase diffusion allows to significantly improve the noise immunity of a device, radically decreasing the dark count rate, but it will also decrease the single photon sensitivity of the considered threshold detector. Quantization of the switching probability tilt versus signal attenuation for various bias currents through the JJ is observed, which resembles the differentiation between N and N+1 photon absorption.

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“…Versions of the Kramers escape rate theory are still being employed in innovative scientific research. For example, this theory as applied to Josephson junctions [6] has recently been used in the design of single photon detectors [7]. The current-voltage characteristics of Josephson junctions can be modelled as a Brownian particle in a tilted periodic potential, where the degree of the tilt is proportional to the bias current and the escape from a potential well corresponds to the creation of a non-zero voltage across the junction.…”

Section: Introductionmentioning

confidence: 99%

On a simple derivation of the very low damping escape rate for classical spins by modifying the method of Kramers

Byrne

Coffey

Kalmykov

et al. 2019

Physica A: Statistical Mechanics and its Applications

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The original perturbative Kramers' method (starting from the phase space coordinates) [H.A. Kramers, Physica 7, 384 (1940)] of determining the energy-controlled-diffusion equation for Newtonian particles with separable and additive Hamiltonians is generalized to yield the energy-controlled diffusion equation and thus the very low damping (VLD) escape rate including spin-transfer torque for classical giant magnetic spins with two degrees of freedom. These have dynamics governed by the magnetic Langevin and Fokker-Planck equations and thus are generally based on non-separable and non-additive Hamiltonians. The derivation of the VLD escape rate directly from the (magnetic) Fokker-Planck equation for the surface distribution of magnetization orientations in the configuration space of the polar and azimuthal angles ( , )

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Detection of Weak Microwave Fields with an Underdamped Josephson Junction

Cited by 56 publications

References 41 publications

Application and fabrication aspects of sub-micrometer-sized Josephson junctions

Application and fabrication aspects of sub-micrometer-sized Josephson junctions

Microwave photon detection by an Al Josephson junction

On a simple derivation of the very low damping escape rate for classical spins by modifying the method of Kramers

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