Measuring the Thermodynamic Cost of Timekeeping

A N Pearson,E A Laird,G A D Briggs,M Huber,Y Guryanova,P Erker,N Ares

doi:10.1103/physrevx.11.021029

Abstract

All clocks, in some form or another, use the evolution of nature towards higher entropy states to quantify the passage of time. Due to the statistical nature of the second law and corresponding entropy flows, fluctuations fundamentally limit the performance of any clock. This suggests a deep relation between the increase in entropy and the quality of clock ticks. Indeed, minimal models for autonomous clocks in the quantum realm revealed that a linear relation can be derived, where for a limited regime every bit of entropy linearly increases the accuracy of quantum clocks. But can such a linear relation persist as we move towards a more classical system? We answer this in the affirmative by presenting the first experimental investigation of this thermodynamic relation in a nanoscale clock. We stochastically drive a nanometer-thick membrane and read out its displacement with a radio-frequency cavity, allowing us to identify the ticks of a clock. We show theoretically that the maximum possible accuracy for this classical clock is proportional to the entropy created per tick, similar to the known limit for a weakly coupled quantum clock but with a different proportionality constant. We measure both the accuracy and the entropy. Once non-thermal noise is accounted for, we find that there is a linear relation between accuracy and entropy and that the clock operates within an order of magnitude of the theoretical bound.

Highlights

By modern standards, the accuracy with which we can keep time is truly astonishing; nowadays the best atomic clocks keep time to an accuracy of approximately one second in every 108 years [1]
Atomic clocks run by the rules of quantum mechanics, targeting a specific hyperfine transition in an atom’s energy spectrum; yet despite the great progress in keeping time, surprisingly little is known about the relation between quantum clocks and thermodynamics
We demonstrated a thermomechanical clock which allowed us to reveal a universal relation in the thermodynamics of timekeeping

Summary

Introduction

The accuracy with which we can keep time is truly astonishing; nowadays the best atomic clocks keep time to an accuracy of approximately one second in every 108 years [1]. One of the milestones at the intersection of the two fields is to derive a quantitative relation between the second law of thermodynamics and the flow of time. Investigations in this direction are a vital component in our understanding of quantum thermodynamics, a field focused on the investigation, analysis, and design of machines on the quantum scale, to which clocks are no exception [10,11]

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