What question did this study set out to answer?

The aim is to explore how finite communication speed affects coordination in technological systems across galaxies.

February 17, 2026Open Access

Irreducible Latency and the Instability of Galactic Restraint: A Structural Filter on the Late-Time Fermi Paradox

Key Points

The aim is to explore how finite communication speed affects coordination in technological systems across galaxies.
Formal modeling of communication speed as a structural selection pressure.
Distinction of origin, propagation, and coordination regimes.
Introduction of a minimal exportability trade model to analyze structural suppression under delayed feedback.
Coordination at galaxy scales becomes unstable when replication times are shorter than communication latency.
The model predicts limited coherence in technosignatures due to environmental constraints rather than lack of technological activity.

Abstract

This paper formalizes finite communication speed as a structural selection pressure on large-scale technological systems. It distinguishes origin, propagation, and coordination regimes and demonstrates that persistent galaxy-scale coordination becomes unstable when replication timescales are shorter than interstellar information latency. A minimal exportability trade model is introduced to show how coordination-dependent architectures are structurally suppressed under delayed feedback and superlinear enforcement overhead. The combined latency–exportability filter predicts the absence of large-scale coherence in technosignatures rather than the absence of technological activity. This work forms a foundational component of the Deep-Time Structural Constraints series.

Irreducible Latency and the Instability of Galactic Restraint: A Structural Filter on the Late-Time Fermi Paradox

Key Points

Abstract

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