What does this research mean for the field?

Elapsed duration in physical and biological clocks is operationally realized through irreversible entropy-producing processes, which can be mathematically modeled as the integral of the entropy production rate. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.ESTABLISHES_NEW_DIRECTION.

What question did this study set out to answer?

This work aims to establish a relationship between irreversible entropy production and the operational measurement of time.

May 17, 2026Open Access

Entropy Production and the Operational Realization of Time in Physical Clocks

Key Points

This work aims to establish a relationship between irreversible entropy production and the operational measurement of time.
Proposes a thermodynamic framework utilizing entropy production rates to derive a functional for time measurement.
Analyzes structural requirements for physical time parameters, such as additivity and robustness.
Explores applications in various systems: clocks, oscillators, and metabolic processes.
Presents a functional relationship for operational time based on entropy production rates.
Suggests that metabolic turnover may influence biological timing through changes in biochemical transitions.
Identifies NADH/NAD⁺ redox dynamics as potential experimental proxies for testing the relationship.

Abstract

This preprint proposes a thermodynamic framework for understanding how physical clocks realize elapsed duration through irreversible entropy-producing processes. While general relativity defines proper time geometrically along a worldline, any real clock that measures duration must instantiate that parameter through physical transitions, stabilization, readout, and memory. The manuscript therefore examines entropy production as an operational substrate of time measurement in real systems. The central proposal is expressed through the functional: τirr=1κ∫S˙prod (t) dt, ₈ₑₑ=1 Ṡ₏ₑ₎₃ (t) \, dt, τirr=κ1∫S˙prod (t) dt, where S˙prodṠ₏ₑ₎₃S˙prod is the entropy production rate and κκ is a system-dependent calibration constant. The framework emphasizes that this relation does not replace geometric proper time; rather, it describes how physical systems may operationally accumulate duration through irreversible change. The article discusses the structural requirements for a physical time parameter, including additivity, monotonicity, and robustness, and applies the framework to physical clocks, chemical oscillators, biological timing systems, and entropy-producing metabolic processes. A qualitative boundary case involving constrained phase-space accessibility in degenerate matter is also considered. A biological extension is outlined through the hypothesis that metabolic turnover may influence biological timing by changing the density of irreversible biochemical transitions. The manuscript proposes NADH/NAD⁺ redox dynamics, including Peredox-type biosensors, as possible experimental proxies for entropy-production-related metabolic turnover. This biological direction is presented as a testable extension rather than as a completed theory of subjective time perception. The work is conceptual and exploratory. Its purpose is to establish a physically grounded correspondence between irreversible entropy production and operational time accumulation, while identifying experimental routes by which the framework may be refined or falsified.

Entropy Production and the Operational Realization of Time in Physical Clocks

Key Points

Abstract

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