Current evaluation practices for advanced artificial agents emphasize performance metrics such as reward, accuracy, or task completion. These metrics often fail to detect structural instabilities that arise under long-horizon operation, especially when optimization signals are sparse, misleading, or adversarial. In this work, we introduce viability horizons: a quantitative framework for detecting impending system collapse in agents subject to irreversible selection pressure. Building on a history-level perspective, we show that collapse is not necessarily preceded by performance degradation, but by loss of internal coherence across time, memory, and control channels. We formalize collapse as a failure to sustain a coherent system history under irreversible updates and demonstrate that alignment, reward maximization, and capability scaling are neither necessary nor sufficient conditions for long-term viability. We propose operational metrics for coherence drift, delayed failure, and irreversibility-induced brittleness, and outline concrete experimental protocols for detecting collapse regimes in contemporary agentic systems. These results reframe AI risk as a structural stability problem rather than a behavioral or normative one. Keywords: artificial intelligence stability, long-horizon coherence, irreversible updates, system collapse, alignment failure modes, cognitive persistence, information loss, entropy accumulation, dynamical systems, AI safety theory
Jonah Brent (Thu,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: