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Main Author: Ritort, F.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.28720
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author Ritort, F.
author_facet Ritort, F.
contents Living cells are energy- and information-processing systems that sustain a nonequilibrium steady state (NESS) by continuously consuming energy and dissipating heat, as required by the second law of thermodynamics. The rate of heat dissipation, or the entropy production rate $σ$, is the universal primal life signal and a unique descriptor of the cellular state. Living matter dissipates $P_{\mathrm{life}} \sim 1$ Watt/kilogram (W/kg), a remarkably conserved value across scales, from molecular reactions to entire organisms. Surprisingly, this high power density is $10^{4}$ times larger than that of the Sun and comparable to the universe's average, $P_U = c^2 H_0 \sim 1$ W/kg, where $c$ is the speed of light and $H_0$ the Hubble constant, a striking coincidence that aligns with Dirac's large number hypothesis. We hypothesize that this large $P_{\mathrm{life}}$ sets the scale for generating negentropy, the negative contribution to the overall positive $σ$ that sustains biological organization, distinguishing animate from inanimate matter. Here, I introduce heatomics, the science of studying $σ$ at the cellular and molecular scales, and the Variance Sum Rule, an experimental--theoretical framework that extracts $σ$ from fluctuations of a dynamical probe combined with the equation of state for a NESS. The emerging field of heatomics aims to elucidate the fundamental principles governing heat power generation, optimization of energy resources, and negentropy in living systems.
format Preprint
id arxiv_https___arxiv_org_abs_2605_28720
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Heatomics
Ritort, F.
Biological Physics
Soft Condensed Matter
A.0
Living cells are energy- and information-processing systems that sustain a nonequilibrium steady state (NESS) by continuously consuming energy and dissipating heat, as required by the second law of thermodynamics. The rate of heat dissipation, or the entropy production rate $σ$, is the universal primal life signal and a unique descriptor of the cellular state. Living matter dissipates $P_{\mathrm{life}} \sim 1$ Watt/kilogram (W/kg), a remarkably conserved value across scales, from molecular reactions to entire organisms. Surprisingly, this high power density is $10^{4}$ times larger than that of the Sun and comparable to the universe's average, $P_U = c^2 H_0 \sim 1$ W/kg, where $c$ is the speed of light and $H_0$ the Hubble constant, a striking coincidence that aligns with Dirac's large number hypothesis. We hypothesize that this large $P_{\mathrm{life}}$ sets the scale for generating negentropy, the negative contribution to the overall positive $σ$ that sustains biological organization, distinguishing animate from inanimate matter. Here, I introduce heatomics, the science of studying $σ$ at the cellular and molecular scales, and the Variance Sum Rule, an experimental--theoretical framework that extracts $σ$ from fluctuations of a dynamical probe combined with the equation of state for a NESS. The emerging field of heatomics aims to elucidate the fundamental principles governing heat power generation, optimization of energy resources, and negentropy in living systems.
title Heatomics
topic Biological Physics
Soft Condensed Matter
A.0
url https://arxiv.org/abs/2605.28720