Correlated Matter Induced Biases in Long-Baseline Neutrino Oscillation Measurements

Abstract

We demonstrate that treating Earth matter effects via a constant-density approximation introduces a fundamental systematic error in long-baseline neutrino oscillation analyses. Using exact numerical propagation through realistic PREM profiles, we show that matter-profile mismodeling does not merely affect the νμ→νe appearance probability, but generates correlated biases across the νμ→ντ and νμ→νμ channels as dictated by PMNS unitarity. Our stochastic analysis reveals that the νμ→ντ channel is the most volatile carrier of the geophysical systematic. Across varying correlation lengths at baselines like 5000 km and 7000 km, the τ-appearance channel consistently carries a larger mean bias and variance than the standard νμ→νe appearance channel. These findings demonstrate that spatially resolved density treatments are a mathematical necessity for the analysis frameworks of future precision neutrino facilities.