Upscaling ground-based backpack gamma-ray spectrometry to spatial resolution of UAV-based gamma-ray spectrometry for system validation

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Sven Altfelder
  • Benedikt Preugschat
  • Milan Matos
  • Felix Kandzia
  • Benjamin Wiens
  • Otabek Eshmuradov
  • Christian Kunze

Research Organisations

External Research Organisations

  • Federal Institute for Geosciences and Natural Resources (BGR)
  • IAF-Radioökologie GmbH
  • Third Element Aviation GmbH
  • Ministry of Mining and Geology of the Republic of Uzbekistan
  • International Atomic Energy Agency (IAEA)
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Details

Original languageEnglish
Article number107382
Number of pages13
JournalJournal of Environmental Radioactivity
Volume273
Early online date23 Jan 2024
Publication statusPublished - Mar 2024

Abstract

Advances in the development of gamma-ray spectrometers have resulted in devices that are ideal for use in conjunction with the increasingly reliable systems of autonomously flying uncrewed aerial vehicles (UAVs) that have recently become available on the market. Airborne gamma-ray spectrometry (GRS) measurements have many different applications. Here, the technique is applied to a former uranium mining and processing site, which is characterized by relatively low specific activities and, hence, low count rates, requiring relatively large detectors and correspondingly big size UAVs. The future acceptance of the use of such UAV-based GRS systems for radionuclide mapping depends on their ability to measure absolute specific activities of natural radionuclides such as U-238 in near-surface soil that are consistent with the results of established and proven ground-based systems. To determine absolute specific activities on the ground, the gamma radiation data from airborne detectors must be corrected for attenuation caused by the flight altitude above ground. In recent years, mathematical procedures for altitude correction have been developed, that are specifically tailored to the working range of several tens of meters typical for UAVs. However, very limited experimental validation of these theoretical approaches is available. A very large dataset consisting of about 3000 UAV-based and 19,000 backpack-based measurements was collected at a low-grade uranium ore dump in Yangiabad, Uzbekistan. We applied different geostatistical interpolation methods to compare the data from both survey techniques by upscaling backpack data to airborne data. Compared to backpack systems, UAV-based systems have lower spatial resolution, so measurements average over larger areal units (or in geostatistical terminology: “spatial support”). Taking into account the change in spatial support, we illustrate that (1) the UAV-based measurements show good agreement with the upscaled backpack measurements and that (2) UAV surveys provide good delineation of contrasts of the relatively smooth U-238 specific activity distribution typical for former uranium mining and processing sites. We are able to show that the resolution of UAV-based systems is sufficient to map extended uranium waste facilities.

Keywords

    (GRS), (UAV), Airborne gamma-ray spectrometry, Kriging, Uncrewed aerial vehicle, Upscaling, Uranium legacy sites, Variogram

ASJC Scopus subject areas

Cite this

Upscaling ground-based backpack gamma-ray spectrometry to spatial resolution of UAV-based gamma-ray spectrometry for system validation. / Altfelder, Sven; Preugschat, Benedikt; Matos, Milan et al.
In: Journal of Environmental Radioactivity, Vol. 273, 107382, 03.2024.

Research output: Contribution to journalArticleResearchpeer review

Altfelder S, Preugschat B, Matos M, Kandzia F, Wiens B, Eshmuradov O et al. Upscaling ground-based backpack gamma-ray spectrometry to spatial resolution of UAV-based gamma-ray spectrometry for system validation. Journal of Environmental Radioactivity. 2024 Mar;273:107382. Epub 2024 Jan 23. doi: 10.1016/j.jenvrad.2024.107382
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title = "Upscaling ground-based backpack gamma-ray spectrometry to spatial resolution of UAV-based gamma-ray spectrometry for system validation",
abstract = "Advances in the development of gamma-ray spectrometers have resulted in devices that are ideal for use in conjunction with the increasingly reliable systems of autonomously flying uncrewed aerial vehicles (UAVs) that have recently become available on the market. Airborne gamma-ray spectrometry (GRS) measurements have many different applications. Here, the technique is applied to a former uranium mining and processing site, which is characterized by relatively low specific activities and, hence, low count rates, requiring relatively large detectors and correspondingly big size UAVs. The future acceptance of the use of such UAV-based GRS systems for radionuclide mapping depends on their ability to measure absolute specific activities of natural radionuclides such as U-238 in near-surface soil that are consistent with the results of established and proven ground-based systems. To determine absolute specific activities on the ground, the gamma radiation data from airborne detectors must be corrected for attenuation caused by the flight altitude above ground. In recent years, mathematical procedures for altitude correction have been developed, that are specifically tailored to the working range of several tens of meters typical for UAVs. However, very limited experimental validation of these theoretical approaches is available. A very large dataset consisting of about 3000 UAV-based and 19,000 backpack-based measurements was collected at a low-grade uranium ore dump in Yangiabad, Uzbekistan. We applied different geostatistical interpolation methods to compare the data from both survey techniques by upscaling backpack data to airborne data. Compared to backpack systems, UAV-based systems have lower spatial resolution, so measurements average over larger areal units (or in geostatistical terminology: “spatial support”). Taking into account the change in spatial support, we illustrate that (1) the UAV-based measurements show good agreement with the upscaled backpack measurements and that (2) UAV surveys provide good delineation of contrasts of the relatively smooth U-238 specific activity distribution typical for former uranium mining and processing sites. We are able to show that the resolution of UAV-based systems is sufficient to map extended uranium waste facilities.",
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note = "Funding Information: The study was funded by the German Federal Ministry of Education and Research ( BMBF ) under the CLIENT II program, Grant No. 01LZ1706A-D . The International Atomic Energy Agency's (IAEA) Coordination Group for Uranium Legacy Sites (CGULS) program has facilitated participation of Central Asian experts in practical workshops and coordination meetings and provided logistical assistance for the field work. CGULS also provided support to practical training of Central Asian experts during the field tests described in this paper. ",
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AU - Altfelder, Sven

AU - Preugschat, Benedikt

AU - Matos, Milan

AU - Kandzia, Felix

AU - Wiens, Benjamin

AU - Eshmuradov, Otabek

AU - Kunze, Christian

N1 - Funding Information: The study was funded by the German Federal Ministry of Education and Research ( BMBF ) under the CLIENT II program, Grant No. 01LZ1706A-D . The International Atomic Energy Agency's (IAEA) Coordination Group for Uranium Legacy Sites (CGULS) program has facilitated participation of Central Asian experts in practical workshops and coordination meetings and provided logistical assistance for the field work. CGULS also provided support to practical training of Central Asian experts during the field tests described in this paper.

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N2 - Advances in the development of gamma-ray spectrometers have resulted in devices that are ideal for use in conjunction with the increasingly reliable systems of autonomously flying uncrewed aerial vehicles (UAVs) that have recently become available on the market. Airborne gamma-ray spectrometry (GRS) measurements have many different applications. Here, the technique is applied to a former uranium mining and processing site, which is characterized by relatively low specific activities and, hence, low count rates, requiring relatively large detectors and correspondingly big size UAVs. The future acceptance of the use of such UAV-based GRS systems for radionuclide mapping depends on their ability to measure absolute specific activities of natural radionuclides such as U-238 in near-surface soil that are consistent with the results of established and proven ground-based systems. To determine absolute specific activities on the ground, the gamma radiation data from airborne detectors must be corrected for attenuation caused by the flight altitude above ground. In recent years, mathematical procedures for altitude correction have been developed, that are specifically tailored to the working range of several tens of meters typical for UAVs. However, very limited experimental validation of these theoretical approaches is available. A very large dataset consisting of about 3000 UAV-based and 19,000 backpack-based measurements was collected at a low-grade uranium ore dump in Yangiabad, Uzbekistan. We applied different geostatistical interpolation methods to compare the data from both survey techniques by upscaling backpack data to airborne data. Compared to backpack systems, UAV-based systems have lower spatial resolution, so measurements average over larger areal units (or in geostatistical terminology: “spatial support”). Taking into account the change in spatial support, we illustrate that (1) the UAV-based measurements show good agreement with the upscaled backpack measurements and that (2) UAV surveys provide good delineation of contrasts of the relatively smooth U-238 specific activity distribution typical for former uranium mining and processing sites. We are able to show that the resolution of UAV-based systems is sufficient to map extended uranium waste facilities.

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