Overview of the Radiation Dosimetry Experiment (RaD-X) flight mission

Mertens, Christopher J.

doi:10.1002/2016sw001399

Cited by 27 publications

(27 citation statements)

References 50 publications

(91 reference statements)

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“…Recently, however, ongoing research into the atmospheric effects of energetic particles has motivated additional measurements. The available data are mainly from limited balloon ascents, usually on special campaigns carrying expensive payloads for recovery after descent [ Mertens , ], and surface GCR measurements from the worldwide network of neutron monitors. It has become clear that one‐off campaigns and neutron monitor data do not adequately represent the spatial and temporal variability of measured ionization profiles [ Aplin et al ., ; Harrison et al ., ; Makhmutov et al ., ], particularly in the weather‐forming region of the atmosphere.…”

Section: Introductionmentioning

confidence: 99%

Measuring ionizing radiation in the atmosphere with a new balloon‐borne detector

et al. 2017

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Increasing interest in energetic particle effects on weather and climate has motivated development of a miniature scintillator‐based detector intended for deployment on meteorological radiosondes or unmanned airborne vehicles. The detector was calibrated with laboratory gamma sources up to 1.3 MeV and known gamma peaks from natural radioactivity of up to 2.6 MeV. The specifications of our device in combination with the performance of similar devices suggest that it will respond to up to 17 MeV gamma rays. Laboratory tests show that the detector can measure muons at the surface, and it is also expected to respond to other ionizing radiation including, for example, protons, electrons (>100 keV), and energetic helium nuclei from cosmic rays or during space weather events. Its estimated counting error is ±10%. Recent tests, when the detector was integrated with a meteorological radiosonde system and carried on a balloon to ~25 km altitude, identified the transition region between energetic particles near the surface, which are dominated by terrestrial gamma emissions, to higher‐energy particles in the free troposphere.

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Section: Introductionmentioning

confidence: 99%

Measuring ionizing radiation in the atmosphere with a new balloon‐borne detector

et al. 2017

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“…The second RaD‐X science goal is to assess the feasibility of specific compact radiation detectors as potential technologies for long‐term, continuous monitoring of the aircraft radiation environment. A more detailed discussion of the background and motivation for the RaD‐X science mission goals is given in the overview of this special issue [ Mertens , ].…”

Section: Introductionmentioning

confidence: 99%

“…These altitudes, combined with the dosimeter and spectrometer instruments, provide a unique measurement data set for improving aviation radiation models. The dose and spectral measurements above the Pfotzer maximum facilitate the characterization of the source of cosmic radiation exposure at aviation altitudes [ Mertens , ]. The balloon flight trajectory near Fort Sumner is located at cutoff rigidities where aviation radiation model uncertainty is near its maximum [ Bottollier‐Depois et al , ].…”

Section: Introductionmentioning

confidence: 99%

Cosmic radiation dose measurements from the RaD-X flight campaign

et al. 2016

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The NASA Radiation Dosimetry Experiment (RaD‐X) stratospheric balloon flight mission obtained measurements for improving the understanding of cosmic radiation transport in the atmosphere and human exposure to this ionizing radiation field in the aircraft environment. The value of dosimetric measurements from the balloon platform is that they can be used to characterize cosmic ray primaries, the ultimate source of aviation radiation exposure. In addition, radiation detectors were flown to assess their potential application to long‐term, continuous monitoring of the aircraft radiation environment. The RaD‐X balloon was successfully launched from Fort Sumner, New Mexico (34.5°N, 104.2°W) on 25 September 2015. Over 18 h of flight data were obtained from each of the four different science instruments at altitudes above 20 km. The RaD‐X balloon flight was supplemented by contemporaneous aircraft measurements. Flight‐averaged dosimetric quantities are reported at seven altitudes to provide benchmark measurements for improving aviation radiation models. The altitude range of the flight data extends from commercial aircraft altitudes to above the Pfotzer maximum where the dosimetric quantities are influenced by cosmic ray primaries. The RaD‐X balloon flight observed an absence of the Pfotzer maximum in the measurements of dose equivalent rate.

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“…The RaD‐X science mission goals are the following: (1) provide measurements that will improve aviation radiation models, such as the Nowcast of Atmospheric Ionizing Radiation for Aviation Safety (NAIRAS) model [ Mertens et al , , ] and (2) intercompare radiation detection instruments to assess their potential application to continuous monitoring of the aviation radiation environment [ Mertens , ]. The RaD‐X balloon flew mainly in two pressure regions: A (18–48 hPa, approximately 21–27 km) and B (<8 hPa, approximately >32 km).…”

Section: Introductionmentioning

confidence: 99%

“…The RaD‐X balloon flew mainly in two pressure regions: A (18–48 hPa, approximately 21–27 km) and B (<8 hPa, approximately >32 km). These regions are above the Pfotzer maximum, i.e., the altitude at which the maximum ionization rate due to the cosmic rays occurs [ Mertens , ]. The radiation environment in these regions is characterized by the influence of cosmic ray primaries, with high‐Z particles (nuclei heavier than the alpha particle) present in Region B and low‐Z and low‐mass particles dominating in Region A.…”

Section: Introductionmentioning

confidence: 99%

Assessment of the influence of the RaD-X balloon payload on the onboard radiation detectors

et al. 2016

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The NASA Radiation Dosimetry Experiment (RaD‐X) stratospheric balloon flight mission, launched on 25 September 2015, provided dosimetric measurements above the Pfotzer maximum. The goal of taking these measurements is to improve aviation radiation models by providing a characterization of cosmic ray primaries, which are the source of radiation exposure at aviation altitudes. The RaD‐X science payload consists of four instruments. The main science instrument is a tissue‐equivalent proportional counter (TEPC). The other instruments consisted of three solid state silicon dosimeters: Liulin, Teledyne total ionizing dose (TID) and RaySure detectors. The instruments were housed in an aluminum structure protected by a foam cover. The structure partially shielded the detectors from cosmic rays but also created secondary particles, modifying the ambient radiation environment observed by the instruments. Therefore, it is necessary to account for the influence of the payload structure on the measured doses. In this paper, we present the results of modeling the effect of the balloon payload on the radiation detector measurements using a Geant‐4 (GEometry ANd Tracking) application. Payload structure correction factors derived for the TEPC, Liulin, and TID instruments are provided as a function of altitude. Overall, the payload corrections are no more than a 7% effect on the radiation environment measurements.

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Overview of the Radiation Dosimetry Experiment (RaD-X) flight mission

Cited by 27 publications

References 50 publications

Measuring ionizing radiation in the atmosphere with a new balloon‐borne detector

Measuring ionizing radiation in the atmosphere with a new balloon‐borne detector

Cosmic radiation dose measurements from the RaD-X flight campaign

Assessment of the influence of the RaD-X balloon payload on the onboard radiation detectors

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