Multiple-tunneling noise in superconducting tunnel junctions from partial current integration

Hiller, L. J.; Berg, M.L. van den; Labov, S. E.

doi:10.1063/1.1428618

Cited by 12 publications

(7 citation statements)

References 9 publications

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“…While, as expected, the new devices exhibit significantly improved detector characteristics, several totally new phenomena have also emerged, including internal amplification due to qp back tunneling, 7 enhanced tunneling and phonon noise, 8,9 and time-dependent tunneling statistics. 10,11 However, the most exciting discovery has been that of a whole new class of phenomena related to the formation of a nonequilibrium, coupled qp-phonon state due to multiple tunneling under bias.…”

Section: Introductionmentioning

confidence: 99%

Dynamics of nonequilibrium quasiparticles in narrow-gap superconducting tunnel junctions

et al. 2008

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The latest generation of high quality, narrow gap, superconducting tunnel junctions ͑STJs͒ exhibits a steadystate and time-dependent behavior which cannot be described satisfactorily by previous treatments of nonequilibrium quasiparticle ͑qp͒ dynamics. These effects are particularly evident in experiments using STJs as detectors of photons, over the range from near infrared to x ray. In this paper, we present a detailed theoretical analysis of the spectral and temporal evolution of the nonequilibrium qp and phonon distributions in such STJs excited by single photons, over a wide range of excitation energy, bias voltage, and temperature. By solving the coupled set of kinetic equations describing the interacting excitations, we show that the nonequilibrium qp distribution created by the initial photoabsorption does not decay directly back to the initial undisturbed state in thermal equilibrium. Instead, it undergoes a rapid adiabatic relaxation to a long-lived, excited state, the spectral distribution of which is nonthermal, maintained by a balance between qp creation, recombination, and trapping. The model is able to describe successfully photoabsorption data taken on several different aluminum STJs, using a single set of parameters. Of particular note is the conclusion that the local traps responsible for qp loss are situated specifically in the region of Nb contacts.

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Section: Introductionmentioning

confidence: 99%

Dynamics of nonequilibrium quasiparticles in narrow-gap superconducting tunnel junctions

et al. 2008

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“…However, as Hiller et al [8] have pointed out, the situation changes for finite integration times. This is most obvious for larger n: after a time t which is short compared to the average tunnel time Γ t −1 it is unlikely to find any sequence of events consisting of n tunnelings, while at a t of the order of several Γ t −1 this probability will be much larger.…”

Section: Time-dependent Tunnel Noisementioning

confidence: 95%

“…Figure 3 illustrates the application of Eq. 9 to a practical example of analogue pulse amplification and shaping using standard methods [8]. The current pulse from an (asymmetric) STJ is pre-amplified and then detected by a two-channel shaping stage, which is the equivalent of a (CR-RC) 2 bipolar semi-Gaussian filter, pole-zero compensated for the preamp.…”

Section: Convolution With the Transfer Function Of The Read-out Electmentioning

confidence: 99%

“…In previous work, we have reported intrinsic energy resolutions below the limit set by the combined tunnel and Fano noise, measured with STJs that do exhibit multiple quasiparticle tunnelling [5,7]. Hiller et al [8] recently pointed out how a careful choice of the pulseintegration time could reduce the tunnel noise. In this paper we present experiments, which support the explanation in terms of the time dependence of the statistics of the tunnel process and we demonstrate how the tunnel noise can be controlled via the pulse integration time.…”

Section: Introductionmentioning

confidence: 96%

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Integration time dependence of tunnel noise and energy resolution of superconducting tunnel junctions

et al. 2003

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Superconducting tunnel junctions (STJs) offer the capability of photon counting with intrinsic energy resolving power. This resolving power is ultimately limited by the variance on the number of charge carriers generated in the photon absorption process (Fano limit) and the variance on the number of tunnelled charge carriers (tunnel limit). In addition, the performance can be degraded by electronic noise related to the read-out of the devices and by spatial nonuniformities in the response across the detector area.The present generation of our Ta-Al STJs is such that their spectroscopic performance in the UV/visible is limited by tunnel noise. This noise contribution is usually considered a device constant, (which may only vary marginally with bias conditions) and evaluated for infinite integration time. It can be shown, however, that the tunnel noise contribution is strongly time dependent and can be reduced by almost an order of magnitude for a properly chosen integration time.In this paper we present the experimental demonstration and numerical simulations of this time dependence on a series of Ta-Al STJs with different pulse decay times. The experimental results are in qualitative agreement with the simulations, but do not quite achieve the predicted performance. For the optimum configuration, an effective tunnel noise contribution of ~70% of the conventional tunnel limit is found.

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“…where ∆ g is the energy gap of the absorbing electrode, E is the photon energy, F is the Fano factor [1,2], G is the statistical broadening due to multiple tunnelling of the quasiparticles [3,4,5,6] and H is the factor due to cancellation tunnel events [7,8], which become important for junctions with a low energy gap. In view of the better predicted energy resolution compared to Ta-based STJs (∆ g =700µeV) we have successfully fabricated high-quality Al-based (∆ g =180µeV) junctions and tested their abilities as NIR to soft-UV photon detectors.…”

Section: Introductionmentioning

confidence: 99%

Optical photon detection in Al superconducting tunnel junctions

Brammertz

Peacock

Verhoeve

et al. 2004

Nuclear Instruments and Methods in Physics Research Section A:

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We report on the successful fabrication of low leakage aluminium superconducting tunnel junctions with very homogeneous and transparent insulating barriers. The junctions were tested in an adiabatic demagnetisation refrigerator with a base temperature of 35 mK. The normal resistance of the junctions is equal to ~7 µΩ cm 2 with leakage currents in the bias voltage domain as low as 100 fA/µm 2 . Optical single photon counting experiments show a very high responsivity with charge amplification factors in excess of 100. The total resolving power λ/∆λ (including electronic noise) for 500 nm photons is equal to 13 compared to a theoretical tunnel limited value of 34. The current devices are found to be limited spectroscopically by spatial inhomogeneities in the detectors response

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Multiple-tunneling noise in superconducting tunnel junctions from partial current integration

Cited by 12 publications

References 9 publications

Dynamics of nonequilibrium quasiparticles in narrow-gap superconducting tunnel junctions

Dynamics of nonequilibrium quasiparticles in narrow-gap superconducting tunnel junctions

Integration time dependence of tunnel noise and energy resolution of superconducting tunnel junctions

Optical photon detection in Al superconducting tunnel junctions

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