Abstract
Airborne Gamma-Ray Spectrometry (AGRS) is a critical tool for radiological emergency response, enabling the rapid identification and quantification of hazardous terrestrial radionuclides over large areas. However, existing calibration methods are inherently limited to only a few gamma-ray sources, excluding most gamma-ray emitting radionuclides released in severe nuclear accidents and nuclear weapon detonations, which in turn compromise effective response and accurate risk assessments in such incidents. Here, we present a high-fidelity Monte Carlo model that overcomes these limitations, offering full-spectrum calibration of any gamma-ray source. Unlike previous approaches, our model integrates a detailed mass model of the entire aircraft and a calibrated non-proportional scintillation model, enabling accurate event-by-event prediction of the spectrometer’s scintillation response to arbitrarily complex gamma-ray fields. Through a series of validation measurements in near-, mid-, and far-field scenarios, we show that the developed model not only effectively addresses the large deficiencies of previous approaches, but also achieves the accuracy and precision required to supersede traditional empirical calibration methods. These results mark a major advancement in AGRS. The developed methodology not only allows for the quantification of any gamma-ray source, but also reduces calibration time and costs, minimizes reliance on high-intensity calibration sources, and eliminates the generation of related radioactive waste. In addition, these advancements offer promising new capabilities for AGRS applications beyond emergency response, including the quantification of the cosmic-ray induced gamma-ray flux in the atmosphere and probing trace-level airborne radionuclides.