Unification of electromagnetic noise and Luttinger liquid via a quantum dot

Hur, Karyn Le; Li, Meirong

doi:10.1103/physrevb.72.073305

Cited by 56 publications

(22 citation statements)

References 29 publications

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“…Since the correlation function of the phase shows the similar power law decay to the chiral bosonic field: he ÀiðtÞ e ið0Þ i $ t À2r and he ÀiÈ ðx¼0;tÞ e iÈ ðx¼0;0Þ i $ t À1 , we can combine the two bosonic fields and introduce a new field [32,40,41]: È ðxÞ ¼ ffiffiffi g p ½È ðxÞ þ ðxÞ with g ¼ 1=ð1 þ 2rÞ, which satisfies he ÀiÈ ðx¼0;tÞ e iÈ ðx¼0;0Þ i $ t À1 . Note that only ðx ¼ 0Þ ¼ has the physical meaning (i.e., phase fluctuation), and ðx Þ 0Þ are auxiliary fields.…”

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confidence: 99%

Proposed Method for Tunneling Spectroscopy with Ohmic Dissipation Using Resistive Electrodes: A Possible Majorana Filter

Liu

2013

Phys. Rev. Lett.

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We propose a scheme to distinguish zero-energy peaks due to Majorana from those due to other effects at finite temperature by simply replacing the normal metallic lead with a resistive lead (large R∼kΩ) in the tunneling spectroscopy. The dissipation effects due to the large resistance change the tunneling conductance significantly in different ways. The Majorana peak remains increase as temperature decreases G∼T(2r-1) for r=e2R/h<1/2. The zero-energy peak due to other effects splits into two peaks at finite temperature and the conductance at zero voltage bias varies with temperature by a power law. The dissipative tunneling with a Majorana mode belongs to the same universal class as the unstable critical point of the case with a non-Majorana mode.

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confidence: 99%

Proposed Method for Tunneling Spectroscopy with Ohmic Dissipation Using Resistive Electrodes: A Possible Majorana Filter

Liu

2013

Phys. Rev. Lett.

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“…First, through similar bosonization and refermionization procedures as in equilibrium, [3][4][5][6] we map our model to an equivalent anisotropic Kondo model in an effective magnetic field h with the effective left L and right R Fermi-liquid leads. 12 The effective Kondo model takes the form Note that ␥ → Ϯ V / 2 near the transition ͑␣ ‫ء‬ → 1 / 2 or ␣ → 1͒ where the above mapping is exact.…”

Section: Model Hamiltonianmentioning

confidence: 99%

“…In recent years, there has been a growing interest in QPTs in nanosystems. [3][4][5][6][7][8][9][10][11] Very recently, QPTs have been extended to nonequilibrium correlated nanosystems [12][13][14] where little is known regarding nonequilibrium transport near the transitions. A generic example 12 is the transport through a dissipative resonance level ͑spinless quantum dot͒ at a finite bias voltage where dissipative bosonic bath ͑noise͒ coming from the environment in the leads gives rise to QPT in transport between a conducting ͑delocalized͒ phase where resonant tunneling dominates and an insulating ͑localized͒ phase where the dissipation prevails.…”

Section: Introductionmentioning

confidence: 99%

“…A generic example 12 is the transport through a dissipative resonance level ͑spinless quantum dot͒ at a finite bias voltage where dissipative bosonic bath ͑noise͒ coming from the environment in the leads gives rise to QPT in transport between a conducting ͑delocalized͒ phase where resonant tunneling dominates and an insulating ͑localized͒ phase where the dissipation prevails. Though dissipative QPTs have been investigated intensively in various systems, 3,4,7,8,12,[15][16][17][18] much of the attention has been focused on equilibrium properties while very little is known on the nonequilibrium properties. The bias voltage V plays a very different role as the temperature T in equilibrium systems as the voltage-induced decoherence behaves very differently from the decoherence at finite temperature, [12][13][14]19,20 leading to exotic transport properties near the QPT compared to that in equilibrium at finite temperatures.…”

Section: Introductionmentioning

confidence: 99%

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Nonequilibrium occupation number and charge susceptibility of a resonance level close to a dissipative quantum phase transition

Chung

Latha

2010

Phys. Rev. B

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Based on the recent paper ͓Phys. Rev. Lett. 102, 216803 ͑2009͔͒, we study the nonequilibrium occupation number n d and charge susceptibility of a resonance level close to dissipative quantum phase transition of the Kosterlitz-Thouless ͑KT͒ type between a delocalized phase for weak dissipation and a localized phase for strong dissipation. The resonance level is coupled to two spinless fermionic baths with a finite bias voltage and an Ohmic bosonic bath representing the dissipative environment. The system is equivalent to an effective anisotropic Kondo model out of equilibrium. Within the nonequilibrium renormalization-group approach, we calculate nonequilibrium magnetization M and spin susceptibility in the effective Kondo model, corresponding to 2n d − 1 and of a resonance level, respectively. We demonstrate the smearing of the KT transition in the nonequilibrium magnetization M as a function of the effective anisotropic Kondo couplings, in contrast to a perfect jump in M at the transition in equilibrium. In the limit of large bias voltages, we find M and at the KT transition and in the localized phase show deviations from the equilibrium Curie-law behavior. As the system gets deeper in the localized phase, both n d −1/ 2 and decrease more rapidly to zero with increasing bias voltages. ͑2͒where c kL͑R͒ † is the electron operator of the effective lead L͑R͒, with spin . Here, the spin operators are related to the electron operators on the dot by S + = d † , S − = d, and S z = d † d −1/ 2=n d −1/ 2, where n d = d † d describes the charge occupancy of the level. The spin operators for electrons in the effective leads are s ␥␤ Ϯ = ͚ ␣,␦,k,k Ј 1 / 2c k␥␣ † ␣␦ Ϯ c k Ј ␤␦ , the transverse and longitudinal Kondo couplings are given by J Ќ 1͑2͒ ϰ t 1͑2͒ and J z ϰ 1 / 2͑1−1/ ͱ 2␣ ‫ء‬ ͒ respectively, and the effective bias voltage is ␥ = Ϯ V 2 ͱ 1 / ͑2␣ ‫ء‬ ͒, where 1 / ␣ ‫ء‬ =1+␣.

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“…In this paper we discuss a system motivated by recent experiments and related theoretical work which study singleparticle electron emitters [15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30] . The model is comprised of a single chiral FQHE edge state coupled to a quantum dot via a quantum point contact (QPC), and we explore the dynamics of this model in a non-equilibrium setup.…”

Section: Introductionmentioning

confidence: 99%

Driven quantum dot coupled to a fractional quantum Hall edge

Wagner¹,

Nguyen²,

Kovrizhin

et al. 2019

Phys. Rev. B

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In relation to recent electron quantum optics experiments we study a model of a quantum dot coupled to a fractional quantum Hall edge driven out of equilibrium by a time-dependent bias voltage. In this setup we take into account short-range interactions between the dot and the edge and calculate the time evolution of the current through the dot using a mapping to a spin-boson problem. Here we present the details of this mapping together with the discussion of numerical results, and their comparison with the perturbative calculations.

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Unification of electromagnetic noise and Luttinger liquid via a quantum dot

Cited by 56 publications

References 29 publications

Proposed Method for Tunneling Spectroscopy with Ohmic Dissipation Using Resistive Electrodes: A Possible Majorana Filter

Proposed Method for Tunneling Spectroscopy with Ohmic Dissipation Using Resistive Electrodes: A Possible Majorana Filter

Nonequilibrium occupation number and charge susceptibility of a resonance level close to a dissipative quantum phase transition

Driven quantum dot coupled to a fractional quantum Hall edge

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