Inverse counting statistics based on generalized factorial cumulants

Stegmann, Philipp; König, Jürgen

doi:10.1088/1367-2630/aa5a70

Cited by 18 publications

(16 citation statements)

References 70 publications

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“…As we will see in the following, the factorial moments and cumulants provide a convenient description of the single-electron micromaser. In particular, while ordinary cumulants are useful to describe continuous random variables, factorial cumulants are in some cases better suited to characterize discrete random variables, such as the number of counted electrons or photons [56][57][58][59][60][61][62][63][64][65][66][67].…”

Section: Full Counting Statisticsmentioning

confidence: 99%

“…Here, by contrast, we show how the phase transitions can be directly observed from accurate measurements of the full counting statistics. In particular, we will see that factorial moments and factorial cumulants [56][57][58][59][60][61][62][63][64][65][66][67] are particularly useful to reveal the non-equilibrium phase transition, which may be observed in future experiments.…”

Section: Introductionmentioning

confidence: 99%

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Nonequilibrium phase transition in a single-electron micromaser

Brange,

Deger,

Flindt

2022

Preprint

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Phase transitions occur in a wide range of physical systems and are characterized by the abrupt change of a physical observable in response to the variation of an external control parameter. Phase transitions are not restricted to equilibrium situations but can also be found in non-equilibrium settings, both for classical and quantum mechanical systems. Here, we investigate a non-equilibrium phase transition in a single-electron micromaser consisting of a microwave cavity that is driven by the electron transport in a double quantum dot. For weak electron-photon couplings, only a tiny fraction of the transferred electrons lead to the emission of photons into the cavity, which essentially remains empty. However, as the coupling is increased, many photons are suddenly emitted into the cavity. Employing ideas and concepts from full counting statistics and Lee-Yang theory, we analyze this non-equilibrium phase transition based on the dynamical zeros of the factorial moment generating function of the electronic charge transport, and we find that the phase transition can be predicted from short-time measurements of the higher-order factorial cumulants. These results pave the way for further investigations of critical behavior in open quantum systems.

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Section: Full Counting Statisticsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nonequilibrium phase transition in a single-electron micromaser

Brange,

Deger,

Flindt

2022

Preprint

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“…so we see that the long-time limit necessarily restricts cumulants to the zero-frequency power regime, where they potentially miss important short-time physics. Counting statistics at finite times, or rather finite frequencies, remain an active theoretical [87][88][89][90][91][92][93][94] and experimental [67] research area; non-Poissonian behavior of higherorder cumulants, for example, has been shown to depend on frequency [95]. Time-dependent current cumulants are able to identify short-time correlations between electrons [96,97]; in fact it has been proposed that higherorder factorial cumulants can be used as a detection technique for electron-electron interactions [98][99][100].…”

Section: Fixed-time Statisticsmentioning

confidence: 99%

Counting quantum jumps: A summary and comparison of fixed-time and fluctuating-time statistics in electron transport

Rudge

Kosov

2019

The Journal of Chemical Physics

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In quantum transport through nanoscale devices, fluctuations arise from various sources: the discreteness of charge carriers, the statistical non-equilibrium that is required for device operation, and unavoidable quantum uncertainty. As experimental techniques have improved over the last decade, measurements of these fluctuations have become available. They have been accompanied by a plethora of theoretical literature using many different fluctuation statistics to describe the quantum transport. In this paper, we overview three prominent fluctuation statistics: full counting, waiting time, and first-passage time statistics. We discuss their weaknesses and strengths, and explain connections between them in terms of renewal theory. In particular, we discuss how different information can be encoded in different statistics when the transport is non-renewal, and how this behavior manifests in the measured physical quantities of open quantum systems. All theoretical results are illustrated via a demonstrative transport scenario: a Markovian master equation for a molecular electronic junction with electron-phonon interactions. We demonstrate that to obtain non-renewal behavior, and thus to have temporal correlations between successive electron tunneling events, there must be a strong coupling between tunneling electrons and out-of-equilibrium quantized molecular vibrations.

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“…3(a) with a solid line, which shows its decaying character. Even though there is an underlying but complex relation between the exponent spectrum and the cumulants [40], the moments µ m = ∞ 0 t m P e (t)dt and the associated cumulants κ m [41] depicted in Fig. 3(b) do not provide direct information about the topology.…”

Section: Introductionmentioning

confidence: 99%

Random-walk topological transition revealed via electron counting

et al. 2017

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The appearance of topological effects in systems exhibiting non-trivial topological band structures strongly relies on the coherent wave nature of the equations of motion. Here, we reveal topological dynamics in a classical stochastic random walk version of the Su-Schrieffer-Heeger model with no relation to coherent wave dynamics. We explain that the commonly used topological invariant in the momentum space translates into an invariant in a counting field space. This quantization gives rise to clear signatures of the topological phase in an associated waiting time distribution.Comment: 8 pages including supplementary information, comments are welcom

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Inverse counting statistics based on generalized factorial cumulants

Cited by 18 publications

References 70 publications

Nonequilibrium phase transition in a single-electron micromaser

Nonequilibrium phase transition in a single-electron micromaser

Counting quantum jumps: A summary and comparison of fixed-time and fluctuating-time statistics in electron transport

Random-walk topological transition revealed via electron counting

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