What question did this study set out to answer?

To establish information-geometric bounds on the energy costs of irreversible computation within thermodynamic systems.

February 22, 2026Open Access

The Demon's Hardware: Information-Geometric Bounds on Thermodynamic Computing

Key Points

To establish information-geometric bounds on the energy costs of irreversible computation within thermodynamic systems.
Derivation of lower bounds based on Fisher information geometry.
Analysis of superconductor computing and extension to general thermodynamic architectures.
Development of falsification conditions for quantum computing systems.
Demonstrated that the Landauer limit is not applicable under opacity constraints.
Established that opacity leads to a multiplicative energy penalty.
Provided testable predictions for performance in quantum computing scenarios.

Abstract

Derives information-geometric lower bounds on the energy cost of irreversible computation, extending Paper 4's superconductor analysis to general thermodynamic computing architectures. Proves that the Landauer limit is not a lower bound for systems operating under opacity constraints — opacity imposes a multiplicative energy penalty derivable from the Fisher information geometry. Provides falsification conditions and testable predictions for quantum computing systems. Part of the Void Framework physics-native series (Papers 4, 4B, 4C, 8).

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Cite This Study

Anthony W. Eckert (Fri,) studied this question.

synapsesocial.com/papers/699a9dcd482488d673cd4051 https://doi.org/https://doi.org/10.5281/zenodo.18717559

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