Airborne Gamma-Ray Spectroscopy for Modeling Cosmic Radiation and Effective Dose in the Lower Atmosphere

et al. 2017

Sensors

Self Cite

Flight height is a fundamental parameter for correcting the gamma signal produced by terrestrial radionuclides measured during airborne surveys. The frontiers of radiometric measurements with UAV require light and accurate altimeters flying at some 10 m from the ground. We equipped an aircraft with seven altimetric sensors (three low-cost GNSS receivers, one inertial measurement unit, one radar altimeter and two barometers) and analyzed ~3 h of data collected over the sea in the (35–2194) m altitude range. At low altitudes (H < 70 m) radar and barometric altimeters provide the best performances, while GNSS data are used only for barometer calibration as they are affected by a large noise due to the multipath from the sea. The ~1 m median standard deviation at 50 m altitude affects the estimation of the ground radioisotope abundances with an uncertainty less than 1.3%. The GNSS double-difference post-processing enhanced significantly the data quality for H > 80 m in terms of both altitude median standard deviation and agreement between the reconstructed and measured GPS antennas distances. Flying at 100 m the estimated uncertainty on the ground total activity due to the uncertainty on the flight height is of the order of 2%.

show abstract

Section: Instruments and Methodsmentioning

confidence: 99%

Accuracy of Flight Altitude Measured with Low-Cost GNSS, Radar and Barometer Sensors: Implications for Airborne Radiometric Surveys

et al. 2017

Sensors

Self Cite

show abstract

“…The latter quantity can indeed be obtained also from the parameters of the linear function describing the relation between the count rates in the BEW and the count rates in the CEW, i.e. : where the fit parameters a BEW , b BEW , A CEW and B CEW have been obtained in an independent aircraft plus cosmic background calibration survey (Baldoncini et al, 2017) 2 .…”

Section: Resultsmentioning

confidence: 99%

“…Gamma-ray measurements are performed with a modular NaI(Tl) scintillation detector arranged in the middle of the Radgyro hull, the AGRS_16L, which is made up of 4 4L crystals having dimensions equal to 10 cm × 10 cm × 40 cm (Guastaldi et al, 2013;Strati et al, 2015). The acquired list mode files, reporting for each ADC channel the energy deposition inside the specific crystal, are processed offline in order to generate for each detector 1Hz energy calibrated gamma spectra, summed up to obtain the gamma-ray spectrum resulting from the whole 16L detection volume (Baldoncini et al, 2017). Radiometric data entering this analysis have been collected at a maximum distance from the coast of about 4.5 km and have been selected by requiring a minimum distance of 300 m, which is meant to exclude gamma-ray signals potentially spoiled by ground radiation.…”

Section: Experimental Setup Survey and Datamentioning

confidence: 99%

Exploring atmospheric radon with airborne gamma-ray spectroscopy

Atmospheric Environment

et al. 2017

Self Cite

Abstract. 222Rn is a noble radioactive gas produced along the 238 U decay chain, which is present in the majority of soils and rocks.As 222 Rn is the most relevant source of natural background radiation, understanding its distribution in the environment is of great concern for investigating the health impacts of low-level radioactivity and for supporting regulation of human exposure to ionizing radiation in modern society. At the same time, 222 Rn is a widespread atmospheric tracer whose spatial distribution is generally used as a proxy for climate and pollution studies. Airborne gamma-ray spectroscopy (AGRS) always treated 222 Rn as a source of background since it affects the indirect estimate of equivalent 238 U concentration. In this work the AGRS method is used for the first time for quantifying the presence of 222 Rn in the atmosphere and assessing its vertical profile.High statistics radiometric data acquired during an offshore survey are fitted as a superposition of a constant component due to the experimental setup background radioactivity plus a height dependent contribution due to cosmic radiation and atmospheric 222Rn. The refined statistical analysis provides not only a conclusive evidence of AGRS 222 Rn detection but also a (0.96 ± 0.07) Bq/m 3 222 Rn concentration and a (1318 ± 22) m atmospheric layer depth fully compatible with literature data.

show abstract

“…As the adopted Monte Carlo simulation method does not structurally provide any background radiation contribution, a cosmic background spectral shape to be subtracted from the experimental measurement is inferred from a 24 hour background calibration measurement according to the approach described in (Baldoncini et al, 2017). Without the introduction of any arbitrary rescaling factor, a good agreement between experimental and simulated spectra is obtained concerning both absolute counting statistics and the spectral shape profile (Figure 9).…”

Section: Simulated and Experimental Spectramentioning

confidence: 88%

Investigating the potentialities of Monte Carlo simulation for assessing soil water content via proximal gamma-ray spectroscopy

Journal of Environmental Radioactivity

et al. 2018

Self Cite