Super- and sub-Poissonian photon statistics for single molecule spectroscopy

He, Yanhu; Barkai, Eli

doi:10.1063/1.1888388

Cited by 32 publications

(43 citation statements)

References 56 publications

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“…where the "partition function" Z(t, s) follows from Eq. (8). These probabilities define an extra counting process, which is parametrized by the dimensionless chemical potential s. Due to this dependence, the set of stochastic realizations consistent with {q n (t, s)} ∞ n=0 is named as the s-ensemble [28,29].…”

Section: A Underlying Thermodynamics and Statistical Mechanicsmentioning

confidence: 99%

Large deviations of ergodic counting processes: A statistical mechanics approach

Budini

2011

Phys. Rev. E

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The large-deviation method allows to characterize an ergodic counting process in terms of a thermodynamic frame where a free energy function determines the asymptotic nonstationary statistical properties of its fluctuations. Here we study this formalism through a statistical mechanics approach, that is, with an auxiliary counting process that maximizes an entropy function associated with the thermodynamic potential. We show that the realizations of this auxiliary process can be obtained after applying a conditional measurement scheme to the original ones, providing is this way an alternative measurement interpretation of the thermodynamic approach. General results are obtained for renewal counting processes, that is, those where the time intervals between consecutive events are independent and defined by a unique waiting time distribution. The underlying statistical mechanics is controlled by the same waiting time distribution, rescaled by an exponential decay measured by the free energy function. A scale invariance, shift closure, and intermittence phenomena are obtained and interpreted in this context. Similar conclusions apply for nonrenewal processes when the memory between successive events is induced by a stochastic waiting time distribution.

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Section: A Underlying Thermodynamics and Statistical Mechanicsmentioning

confidence: 99%

Large deviations of ergodic counting processes: A statistical mechanics approach

Budini

2011

Phys. Rev. E

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“…Trivially, one can write δ RRst(τ ) = P R (τ ), where {P R (t)} are the solution of Eq. (14). After assuming that n st R (0) = 0 and P R (0) = P ∞ R [Eq.…”

Section: A Stochastic Approachmentioning

confidence: 99%

Thermodynamics of quantum jump trajectories in systems driven by classical fluctuations

Budini¹

2010

Phys. Rev. E

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The large-deviation method can be used to study the measurement trajectories of open quantum systems. For optical arrangements this formalism allows to describe the long time properties of the (nonequilibrium) photon counting statistics in the context of a (equilibrium) thermodynamic approach defined in terms of dynamical phases and transitions between them in the trajectory space [J. P. Garrahan and I. Lesanovsky, Phys. Rev. Lett. 104, 160601 (2010)]. In this paper, we study the thermodynamic approach for fluorescent systems coupled to complex reservoirs that induce stochastic fluctuations in their dynamical parameters. In a fast modulation limit the thermodynamics corresponds to that of a Markovian two-level system. In a slow modulation limit, the thermodynamic properties are equivalent to those of a finite system that in an infinite-size limit is characterized by a first-order transition. The dynamical phases correspond to different intensity regimes, while the size of the system is measured by the transition rate of the bath fluctuations. As a function of a dimensionless intensive variable, the first and second derivatives of the thermodynamic potential develop an abrupt change and a narrow peak, respectively. Their scaling properties are consistent with a double-Gaussian probability distribution of the associated extensive variable.

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“…It comes as no surprise that considerable effort has been expended on the theory of interpreting/modeling SMS trajectories, at various levels of sophistication. 8, Recent work by us [37][38][39][40][41][42][43][44][45] and others [46][47][48][49][50] has established generating function techniques as a somewhat general means for calculating statistical quantities of single molecule photon counting experiments, including quantum mechanical evolution of the chromophore. The only fundamental limitations to this approach are that you must consider the spontaneous emission of photons to be governed by rate processes and the directly calculated quantities are statistical moments and probabilities of the number of photons emitted over a given time interval.…”

Section: Introductionmentioning

confidence: 99%

Single-molecule photon emission statistics for systems with explicit time dependence: Generating function approach

Peng

Xie

Zheng

et al. 2009

The Journal of Chemical Physics

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Super- and sub-Poissonian photon statistics for single molecule spectroscopy

Cited by 32 publications

References 56 publications

Large deviations of ergodic counting processes: A statistical mechanics approach

Large deviations of ergodic counting processes: A statistical mechanics approach

Thermodynamics of quantum jump trajectories in systems driven by classical fluctuations

Single-molecule photon emission statistics for systems with explicit time dependence: Generating function approach

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