NDGRI: A Novel Sentinel-2 Normalized Difference Gamma-Radiation Index for Pixel-Level Detection of Elevated Gamma Radiation

This study introduces the Normalized Difference Gamma Ray Index (NDGRI), a novel spectral composite derived from Sentinel 2 imagery for mapping elevated natural gamma radiation in semi arid and arid basins. We hypothesized that water‐sensitive spectral indices correlate with gamma‐ray hotspots in arid regions of Mongolia, where natural radionuclide distribution is influenced by hydrological processes. Leveraging historical car-borne gamma spectrometry data collected in 2008 across the Sainshand and Zuunbayan uranium project areas, we evaluated twelve spectral bands and five established moisture-sensitive indices against radiation heatmaps in Naarst and Zuunbayan. Using Pearson and Spearman correlations alongside two percentile based overlap metrics, indices were weighted to yield a composite performance score. The best performing indices (MI - Moisture Index and NDSII_1 - Normalized Difference Snow and Ice Index) guided the derivation of ten new ND constructs incorporating SWIR bands (B11, B12) and visible bands (B4, B8A). The top performer, NDGRI = (B4–B12)/(B4 + B12) achieved a precision of 62.8% for detecting high gamma‐radiation areas and outperformed benchmarks of other indices. We established climatological screening criteria to ensure NDGRI reliability. Validation at two independent sites (Erdene, Khuvsgul) using 2008 airborne gamma ray heatmaps yielded 68.1% and 45.4% overlap, respectively. Our results demonstrate that NDGRI effectively delineates gamma radiation hotspots where moisture controlled spectral contrasts prevail. The index’s stringent acquisition constraints, however, limit temporal availability of usable scenes. NDGRI offers a rapid, cost effective remote sensing tool to prioritize ground surveys in uranium prospective basins and may be adapted for other radiometric applications in semi arid and arid regions.