Dephasing of electrons in mesoscopic metal wires

Pierre, F.; Gougam, Adel; Anthore, A.; Pothier, H.; Estève, D.; Birge, Norman O.

doi:10.1103/physrevb.68.085413

Cited by 213 publications

(319 citation statements)

References 43 publications

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“…For W ≥ 3.5 × 10 −10 W the response becomes non-linear. The measured responsivities agree within 10% to the predicted disconnected thermal model responsivities with literature [12,13], and fit values. The measured responsivities only agree within 50% to the ideal model.…”

Section: Responsivity Measurementssupporting

confidence: 64%

“…The fitted e-p values and conductances for both models are listed in Table 1. The disconnected model fits to values only slightly lower than literature values [12,13]. In all cases the ep conductance is substantially greater than the e-e conductance along the absorber, further supporting a disconnected model for this test device.…”

Section: W Vs T Bath and Thermal Conductance Measurementssupporting

confidence: 50%

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Sensitivity Measurements of a Transition-Edge Hot-Electron Microbolometer for Millimeter-Wave Astrophysical Observations

et al. 2008

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Future experiments to probe the Cosmic Microwave Background (CMB) polarization will need arrays of 1000s of sensitive bolometers. We are developing a Transition-edge Hot-electron Microbolometer (THM) to fill this need. This small-volume bolometer consists of a superconducting bilayer Transition-Edge Sensor (TES) with a thin-film absorber. Unlike traditional monolithic bolometers which make use of micromachined structures, the THM employs the decoupling between electrons and phonons at milliKelvin temperatures to provide thermal isolation. The devices are fabricated photolithographically and are easily integrated with antennas via microstrip transmission lines, and with SQUID readouts. We present the results of noise, responsivity, and thermal conductance measurements in which electrical power is dissipated in the absorber, and confirm a thermal model for a test THM with a Mo/Au TES and Bi/Au absorber.

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Section: Responsivity Measurementssupporting

confidence: 64%

Section: W Vs T Bath and Thermal Conductance Measurementssupporting

confidence: 50%

Sensitivity Measurements of a Transition-Edge Hot-Electron Microbolometer for Millimeter-Wave Astrophysical Observations

et al. 2008

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“…This constructive interference can, however, be reduced by applying an external magnetic field, so the measured electrical resistance is a maximum at zero applied field and falls to the classical resistance value as the magnetic field is increased-a hallmark of weak localization. Weak localization also has a very characteristic temperature dependence, as elevating the temperature increases the inelastic scattering rate, thereby suppressing the constructive interference and reducing the weak localization resistance peak 15,16 . Given that quantum interference lies at the heart of weak localization, it is natural to use wave-like systems to emulate this effect.…”

mentioning

confidence: 99%

Emulating weak localization using a solid-state quantum circuit

et al. 2014

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Quantum interference is one of the most fundamental physical effects found in nature. Recent advances in quantum computing now employ interference as a fundamental resource for computation and control. Quantum interference also lies at the heart of sophisticated condensed matter phenomena such as Anderson localization, phenomena that are difficult to reproduce in numerical simulations. Here, employing a multiple-element superconducting quantum circuit, with which we manipulate a single microwave photon, we demonstrate that we can emulate the basic effects of weak localization. By engineering the control sequence, we are able to reproduce the well-known negative magnetoresistance of weak localization as well as its temperature dependence. Furthermore, we can use our circuit to continuously tune the level of disorder, a parameter that is not readily accessible in mesoscopic systems. Demonstrating a high level of control, our experiment shows the potential for employing superconducting quantum circuits as emulators for complex quantum phenomena.

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“…13 . The situation here is to be contrasted with the absence of spin disorder, where it has been shown that…”

mentioning

confidence: 99%

“…Decoherence arises from coulombic interactions, scattering by phonons, magnetic fluctuations etc. The saturation of the dephasing rate at low temperature T seen in numerous experiments [1][2][3][4][5][6][7][8][9][10][11][12][13] has attracted a vigorous interest, especially given the longstanding theoretical prediction for a vanishing τ −1 φ as the temperature T → 0. [14][15][16][17][18][19][20][21] .…”

mentioning

confidence: 99%

Low-temperature dephasing saturation from elastic magnetic spin disorder and interactions

Kastrinakis

2005

Phys. Rev. B

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We treat the question of the low temperature behavior of the dephasing rate of the electrons in the presence of elastic spin disorder scattering and interactions. In the frame of a self-consistent diagrammatic treatment, we obtain saturation of the dephasing rate in the limit of low temperature for magnetic scattering, in agreement with the non-interacting case. The magnitude of the dephasing rate is set by the strength of the magnetic scattering rate. We discuss the agreement of our results with relevant experiments.An important quantity in disordered electronic systems is the dephasing rate τ −1 φ . It provides a measure of the loss of coherence of the carriers, but in the two-particle channel -c.f. eq. (1) below. Decoherence arises from coulombic interactions, scattering by phonons, magnetic fluctuations etc. The saturation of the dephasing rate at low temperature T seen in numerous experiments 1-13 has attracted a vigorous interest, especially given the longstanding theoretical prediction for a vanishing τ −1 φ as the temperature T → 0. 14-21 . Previous theoretical studies 14-25 have focused on the calculation of τ −1 φ in the absence of spin-scattering disorder. The majority of these studies predict, correctly, a vanishing τ −1 φ (T → 0) . Here we determine and calculate the factors which contribute to dephasing in the presence of spin-scattering disorder. The saturation obtained allows for the consistent elucidation of this puzzle.In the presence of spin-less disorder, the cooperon (particle-particle diffusion correlator -c.f. fig. 1) is given byD is the diffusion coefficient, N F is the density of states at the Fermi level and τ −1 the total impurity scattering rate. We work in the diffusive regime ǫ F τ > 1 (h = 1), ǫ F being the Fermi energy. With spin-disorder present, the cooperon becomes spin-dependent. The relevant terms C i are shown in fig. 1. We start by giving the explicit form of these C o 0,1,2 without a dephasing rate. C o 0 acquires a finite spin-dependent term in the denominator, which is crucial for the determination of the dephasing rate -c.f. below.For the case , τ −1 S > 0, τ −1 so = 0 -with τ −1 S the magnetic impurity scattering rate and τ −1 so the spin-orbit impurity scattering rate -the cooperons are given byBased on eqs. (2), we expect a saturation of the dephasing rate. The simple diffusion pole is "cut-off" by the constant terms proportional to τ −1 S . On symmetry grounds, the spin-conserving Coulomb interaction cannot eliminate these terms.We emphasize that the impurity scattering considered is elastic, bulk-type. Interfacial impurity scattering, though similar to bulk-type, is expected to differ in detail.To calculate the dephasing rate, we write down and solve the appropriate coupled equations for all three renormalized cooperons C i (q, ω), i = 0, 1, 2. We note that usually the terms containing the factors d i and h i below are completely omitted. The equations are shown schematically in fig. 2:

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Dephasing of electrons in mesoscopic metal wires

Cited by 213 publications

References 43 publications

Sensitivity Measurements of a Transition-Edge Hot-Electron Microbolometer for Millimeter-Wave Astrophysical Observations

Sensitivity Measurements of a Transition-Edge Hot-Electron Microbolometer for Millimeter-Wave Astrophysical Observations

Emulating weak localization using a solid-state quantum circuit

Low-temperature dephasing saturation from elastic magnetic spin disorder and interactions

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