Thermodynamics of Computations with Absolute Irreversibility, Unidirectional Transitions, and Stochastic Computation Times

Manzano, Gonzalo; Kardeş, Gülce; Roldán, Édgar; Wolpert, David H.

doi:10.1103/physrevx.14.021026

Phys. Rev. X

2024

DOI: 10.1103/physrevx.14.021026

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Thermodynamics of Computations with Absolute Irreversibility, Unidirectional Transitions, and Stochastic Computation Times

Gonzalo Manzano,

Gülce Kardeş,

Édgar Roldán

et al.

Abstract: Developing a thermodynamic theory of computation is a challenging task at the interface of nonequilibrium thermodynamics and computer science. In particular, this task requires dealing with difficulties such as stochastic halting times, unidirectional (possibly deterministic) transitions, and restricted initial conditions, features common in real-world computers. Here, we present a framework which tackles all such difficulties by extending the martingale theory of nonequilibrium thermodynamics to generic nonst… Show more

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Cited by 4 publications

References 108 publications

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Martingales for physicists: a treatise on stochastic thermodynamics and beyond

Roldán,

Neri,

Chetrite

et al. 2023

Advances in Physics

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Martingales for physicists: a treatise on stochastic thermodynamics and beyond

Roldán,

Neri,

Chetrite

et al. 2023

Advances in Physics

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Broken detailed balance and entropy production in directed networks

Nartallo-Kaluarachchi,

Asllani,

Deco

et al. 2024

Phys. Rev. E

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The structure of a complex network plays a crucial role in determining its dynamical properties. In this paper , we show that the the degree to which a network is directed and hierarchically organized is closely associated with the degree to which its dynamics break detailed balance and produce entropy. We consider a range of dynamical processes and show how different directed network features affect their entropy production rate. We begin with an analytical treatment of a two-node network followed by numerical simulations of synthetic networks using the preferential attachment and Erdös-Renyi algorithms. Next, we analyze a collection of 97 empirical networks to determine the effect of complex real-world topologies. Finally, we present a simple method for inferring broken detailed balance and directed network structure from multivariate time series and apply our method to identify non-equilibrium dynamics and hierarchical organisation in both human neuroimaging and financial time series. Overall, our results shed light on the consequences of directed network structure on non-equilibrium dynamics and highlight the importance and ubiquity of hierarchical organisation and non-equilibrium dynamics in real-world systems. Published by the American Physical Society 2024

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Thermodynamic Bounds on Symmetry Breaking in Linear and Catalytic Biochemical Systems

Liang,

De Los Rios,

Busiello

2024

Phys. Rev. Lett.

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Living systems are maintained out of equilibrium by external driving forces. At stationarity, they exhibit emergent selection phenomena that break equilibrium symmetries and originate from the expansion of the accessible chemical space due to nonequilibrium conditions. Here, we use the matrix-tree theorem to derive upper and lower thermodynamic bounds on these symmetry-breaking features in linear and catalytic biochemical systems. Our bounds are independent of the kinetics and hold for both closed and open reaction networks. We also extend our results to master equations in the chemical space. Using our framework, we recover the thermodynamic constraints in kinetic proofreading. Finally, we show that the contrast of reaction-diffusion patterns can be bounded only by the nonequilibrium driving force. Our results provide a general framework for understanding the role of nonequilibrium conditions in shaping the steady-state properties of biochemical systems. Published by the American Physical Society 2024

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Thermodynamics of Computations with Absolute Irreversibility, Unidirectional Transitions, and Stochastic Computation Times

Cited by 4 publications

References 108 publications

Martingales for physicists: a treatise on stochastic thermodynamics and beyond

Martingales for physicists: a treatise on stochastic thermodynamics and beyond

Broken detailed balance and entropy production in directed networks

Thermodynamic Bounds on Symmetry Breaking in Linear and Catalytic Biochemical Systems

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