Heat flow due to time-delayed feedback

Loos, Sarah A. M.; Klapp, Sabine H. L.

doi:10.1038/s41598-019-39320-0

Cited by 39 publications

(58 citation statements)

References 59 publications

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“…This implies, at least for Markovian systems, the existence of steady-state probability currents in the state space, which change sign under time-reversal. When a thermodynamically consistent description is available, the average rate of entropy production can be related to the rate of energy or information exchange between the system, the heat bath(s) it is connected to, and any other thermodynamic entity involved in the dynamics, such as a measuring device [ 15 , 16 , 17 ]. Whilst the rate of energy dissipation is of immediate interest since it captures how ‘costly’ it is to sustain specific dynamics (e.g., the metabolism sustaining the development of an organism [ 18 , 19 ]), entropy production has also been found to relate non-trivially to the efficiency and precision of the corresponding process via uncertainty relations [ 3 , 20 ].…”

Section: Introductionmentioning

confidence: 99%

Entropy Production in Exactly Solvable Systems

Cocconi

Garcia-Millan

Zhen

et al. 2020

Entropy

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The rate of entropy production by a stochastic process quantifies how far it is from thermodynamic equilibrium. Equivalently, entropy production captures the degree to which global detailed balance and time-reversal symmetry are broken. Despite abundant references to entropy production in the literature and its many applications in the study of non-equilibrium stochastic particle systems, a comprehensive list of typical examples illustrating the fundamentals of entropy production is lacking. Here, we present a brief, self-contained review of entropy production and calculate it from first principles in a catalogue of exactly solvable setups, encompassing both discrete- and continuous-state Markov processes, as well as single- and multiple-particle systems. The examples covered in this work provide a stepping stone for further studies on entropy production of more complex systems, such as many-particle active matter, as well as a benchmark for the development of alternative mathematical formalisms.

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Section: Introductionmentioning

confidence: 99%

Entropy Production in Exactly Solvable Systems

Cocconi

Garcia-Millan

Zhen

et al. 2020

Entropy

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“…From Eq. (39) we see that next to the term expressing the singlemode solution, additional terms describing mode-to-mode coupling emerge, which describe mutual heating effects. For independent modes (such that |ω 1 − ω 2 | → ∞) the mutual heating vanishes.…”

Section: Simultaneous Cooling Of Two Adjacent Modesmentioning

confidence: 91%

“…We provide here a more in-depth analytical treatment of simultaneous cold damping of many mechanical resonances [33][34][35] and address a crucial aspect extremely relevant in experiments, i.e., the inherent time delay τ inh that characterizes any electronic feedback loop. It is generally agreed that the delayed action of the feedback loop can lead to unwanted heating eventually leading to an instability [36][37][38][39]. Extending the analytical approach that we have previously introduced in Ref.…”

Section: Introductionmentioning

confidence: 93%

Multimode cold-damping optomechanics with delayed feedback

Sommer

Ghosh

Genes

2020

Phys. Rev. Research

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We investigate the role of time delay in cold-damping optomechanics with multiple mechanical resonances. For instantaneous electronic response, it was recently shown by C. Sommer and C. Genes [Phys. Rev. Lett. 123, 203605 (2019)] that a single feedback loop is sufficient to simultaneously remove thermal noise from many mechanical modes. While the intrinsic delayed response of the electronics can induce single-mode and mutual heating between adjacent modes, we propose to counteract such detrimental effects by introducing an additional time delay to the feedback loop. For lossy cavities and broadband feedback, we derive analytical results for the final occupancies of the mechanical modes within the formalism of quantum Langevin equations. For modes that are frequency degenerate collective effects dominate, mimicking behavior similar to Dicke super-and subradiance. These analytical results, corroborated with numerical simulations of both transient and steady state dynamics, allow us to find suitable conditions and strategies for efficient single-mode or multimode feedback optomechanics.

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“…It is important to underline that one can not explicitly calculate the underdamped susceptibilities and take the massless limit m → 0 afterwards because this would lead to inconsistencies, as it can be seen in [22]. However, the direct solution of the overdamped dynamics (63) can be found (dropping the "over" superscript):…”

Section: Overdamped Dynamicsmentioning

confidence: 99%

Explicit Solution of the Generalised Langevin Equation

2020

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Generating an initial condition for a Langevin equation with memory is a non trivial issue. We introduce a generalisation of the Laplace transform as a useful tool for solving this problem, in which a limit procedure may send the extension of memory effects to arbitrary times in the past. This method allows us to compute average position, work, their variances and the entropy production rate of a particle dragged in a complex fluid by an harmonic potential, which could represent the effect of moving optical tweezers. For initial conditions in equilibrium we generalise the results by van Zon and Cohen, finding the variance of the work for generic protocols of the trap. In addition, we study a particle dragged for a long time captured in an optical trap with constant velocity in a steady state. Our formulas open the door to thermodynamic uncertainty relations in systems with memory.

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Heat flow due to time-delayed feedback

Cited by 39 publications

References 59 publications

Entropy Production in Exactly Solvable Systems

Entropy Production in Exactly Solvable Systems

Multimode cold-damping optomechanics with delayed feedback

Explicit Solution of the Generalised Langevin Equation

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