Electron quantum optics in ballistic chiral conductors

Bocquillon, Erwann; Freulon, Vincent; Parmentier, François; Berroir, Jean-Marc; Plaçais, Bernard; Wahl, Claire; Rech, Jérôme; Jonckheere, Thibaut; Martin, Thierry; Grenier, Charles; Ferraro, Dario; Degiovanni, Pascal; Fève, Gwendal

doi:10.1002/andp.201300181

Cited by 187 publications

(235 citation statements)

References 129 publications

(188 reference statements)

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“…The injection of a single polarized electron into the EC can thus be achieved with an abrupt change of the top gate potential at time t = 0. Consequently, the most energetic electron in the QD, chosen here with spin up, is suddenly brought above E F and leaves it [19,48] tunneling into the helical edges. In this paper, we will assume that the spin-preserving tunneling is the dominant mechanism, and we thus restrict the discussion to this case.…”

Section: Setup and General Modelmentioning

confidence: 99%

“…Moreover, we explicitly take into account the finite lifetime 1/2γ of the QD level [19,71] by assuming the time evolution of QD correlator d † (t 1 )d(t 2 ) = β * (t 1 )β(t 2 ), with…”

Section: A Single Electron Injectionmentioning

confidence: 99%

“…Nevertheless, an accurate description and understanding of energy dynamics for time-dependent single electron injection in an interacting system is still lacking, despite the fact that it will play an important role in the fast developing field of electron quantum optics [18,19]. This very promising field relies on the possibility of injecting single electrons and holes into one-dimensional (1D) systems.…”

Section: Introductionmentioning

confidence: 99%

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Time-resolved energy dynamics after single electron injection into an interacting helical liquid

et al. 2016

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The possibility of injecting a single electron into ballistic conductors is at the basis of the new field of electron quantum optics. Here, we consider a single electron injection into the helical edge channels of a topological insulator. Their counterpropagating nature and the unavoidable presence of electron-electron interactions dramatically affect the time evolution of the single wave packet. Modeling the injection process from a mesoscopic capacitor in the presence of nonlocal tunneling, we focus on the time-resolved charge and energy packet dynamics. Both quantities split up into counterpropagating contributions whose profiles are strongly affected by the interaction strength. In addition, stronger signatures are found for the injected energy, which is also affected by the finite width of the tunneling region, in contrast to what happens for the charge. Indeed, the energy flow can be controlled by tuning the injection parameters, and we demonstrate that, in the presence of nonlocal tunneling, it is possible to achieve a situation in which charge and energy flow in opposite directions.

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Section: Setup and General Modelmentioning

confidence: 99%

“…Moreover, we explicitly take into account the finite lifetime 1/2γ of the QD level [19,71] by assuming the time evolution of QD correlator d † (t 1 )d(t 2 ) = β * (t 1 )β(t 2 ), with…”

Section: A Single Electron Injectionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Time-resolved energy dynamics after single electron injection into an interacting helical liquid

et al. 2016

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“…For other energies the correlation function is zero, what is specific for purely electronic excitations. 39 Note that G…”

Section: The Purity Condition In Time and Energy Representationsmentioning

confidence: 99%

“…A non-zero value of G (1),in ac in the electron-hole sector, n ≥ 0, ν ≤ 0 or n < 0, ν > 0, indicates the presence of electron-hole correlations. 32,33,39 Note that in the electron-hole sector the sum on the RHS of the second line of Eq. (7) is zero due to cancellation of electron and hole contributions, which is specific for states with equal number of electrons and holes.…”

mentioning

confidence: 99%

First-order correlation function of a stream of single-electron wave packets

Moskalets

2015

Phys. Rev. B

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The first-order correlation function, which is accessible experimentally, contains all essential information about the state of the system of non-interacting electrons. Here I discuss how this function can be used to answer the question whether the state of a periodic stream of single-electron wavepackets is a multi-particle state or it is the product of single-particle states. In the latter case the correlation function is expected to be factorizable while in the former case it is not. As an example I consider a train of Lorentzian in shape single-electron excitations, levitons. I demonstrate that the correlation function in time domain is factorizable or not depending on whether the wave-packets are separated or overlapping. In contrast, the correlation function in energy domain is always factorizable and thus cannot be used to distinguish single-and multi-particle states.

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More “Critical Mass”, Higher Quality and Visibility of Annalen der Physik

Hildebrandt¹

2017

Annalen der Physik

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Electron quantum optics in ballistic chiral conductors

Cited by 187 publications

References 129 publications

Time-resolved energy dynamics after single electron injection into an interacting helical liquid

Time-resolved energy dynamics after single electron injection into an interacting helical liquid

First-order correlation function of a stream of single-electron wave packets

More “Critical Mass”, Higher Quality and Visibility of Annalen der Physik

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