Abstract This paper formalizes the Law of Critical Sensitivity and Impact Disproportionality (LCSID), a theoretical framework that redefines risk assessment in high-density energetic systems. LCSID posits that in high-sensitivity environments, the magnitude of impact (I) remains catastrophic regardless of probability minimization. The research establishes the Principle of Sequential Weighting, demonstrating that identified lapses (Lₙ) carry cumulative systemic stress that scales based on the order of discovery. A central contribution of this work is the formalization of the Unidentified Variable (Lₓ), which represents 'Unknown-Unknown' risks. Through mathematical grounding in asymptotic limits, the paper proves that absolute security is a theoretical limit (Lₓ 0) rather than an attainable state. Building upon these postulates, the study introduces the "-26 Limit Standard, " a critical safety mandate that mathematically constrains the total impact (Iₓ₎ₓ₀₋) to below 26% of a system's operational capacity. This is achieved through the integration of Spatial and Temporal Decentralization (Modularization) and Sensitivity Threshold Management (STM). By analyzing the Paradox of Anticipated Risk, the study concludes that systemic integrity is paradoxically enhanced by the high anticipation of latent vulnerabilities. The findings suggest that a zero-value Lₓ is a diagnostic indicator of an 'observation blind spot' rather than actual safety, necessitating a cognitive shift from passive monitoring to a Perpetual Discovery Mandate. Keywords: LCSID Framework, Systemic Integrity, Latent Risk (Lₓ), Asymptotic Security, Sequential Risk Weighting, -26 Limit Standard, Impact Containment, Modularization, Sensitivity Threshold Management, Risk-Impact Inversion, Perpetual Discovery Mandate, High-Density Energetic Systems.
Ayyappan Manikantan Nair (Tue,) studied this question.