What question did this study set out to answer?

This research aims to detect and classify structural anomalies in small modular reactors using the LESE-EIA framework.

synapse

⌘+K

synapse

⌘+K

June 9, 2026Open Access

Structural Coherence Analysis of Nuclear Reactor Anomalies in Small Modular Reactors via LESE-EIA Framework

Key Points

This research aims to detect and classify structural anomalies in small modular reactors using the LESE-EIA framework.
Applied LESE-EIA framework to the PWR-SMR-2026-01 dataset with 1,518 high-fidelity OpenMC statepoints.
Conducted volumetric and scalar analyses at a mesh of 70×70×50.
Achieved 100% recall with no calibration parameters.
LESE coherence metric established a universal fragility threshold W* = e⁻¹ ≈ 0.3679.
Successfully detected fuel temperature perturbations below Monte Carlo noise floor.
Zero calibration parameters enabled reliable anomaly detection.

Abstract

We apply the LESE-EIA framework to the detection and structural classification of anomalies in small modular reactors (SMRs), using the PWR-SMR-2026-01 dataset (1,518 high-fidelity OpenMC statepoints, three anomaly classes). The LESE coherence metric is derived from the single postulate dW/dτ = κ(1+log W), yielding the universal fragility threshold W* = e⁻¹ ≈ 0.3679 without calibration. Analysis at volumetric level (70×70×50 mesh) and scalar level (all 1,518 statepoints) achieves 100% recall with zero calibration parameters. LESE captures structural deviation for fuel temperature perturbations below the Monte Carlo noise floor that single-frame statistical methods cannot detect.

Structural Coherence Analysis of Nuclear Reactor Anomalies in Small Modular Reactors via LESE-EIA Framework

Key Points

Abstract

Cite This Study

Also Consider

Also Consider