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AniMAIRE -- A New Openly Available Tool for Calculating Atmospheric Ionising Radiation Dose Rates and Single Event Effects During Anisotropic Conditions (2405.03818v2)

Published 6 May 2024 in physics.app-ph, physics.comp-ph, and physics.space-ph

Abstract: AniMAIRE (Anisotropic Model for Atmospheric Ionising Radiation Effects) is a new model and Python toolkit for calculating radiation dose rates experienced by aircraft during anisotropic solar energetic particle events. AniMAIRE expands the physics of the MAIRE+ model such that dose rate calculations can be performed for anisotropic solar energetic particle conditions by supplying a proton or alpha particle rigidity spectrum, a pitch angle distribution, and the conditions of Earth's magnetosphere. In this paper, we describe the algorithm and top-level structure of AniMAIRE and showcase AniMAIRE's capabilities by analysing the dose rate maps that AniMAIRE produces when the time-dependent spectra and pitch angle distribution for GLE71 are inputted. We find that the dose rates AniMAIRE produces for the event fall between the dose rates produced by the WASAVIES and CRAC:DOMO models. Dose rate maps that evolve throughout the event are also shown, and it is found that each peak in the inputted pitch angle distribution generates a dose rate hotspot in each of the polar regions. AniMAIRE has been made available openly online so that it can be downloaded and run freely on local machines and so that the space weather community can easily contribute to it using Github forking.

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References (48)
  1. \APACinsertmetastarPySpaceWeather{APACrefauthors}Bender, S.  \APACrefYearMonthDay\bibnodate. \BBOQ\APACrefatitlePySpaceWeather PySpaceWeather\BBCQ [\bibcomputersoftware]. {APACrefURL} https://github.com/st-bender/pyspaceweather \APACrefnoteversion 0.2.4 \PrintBackRefs\CurrentBib
  2. \APACrefYearMonthDay2018. \BBOQ\APACrefatitleSolar energetic particle events observed by the PAMELA mission Solar energetic particle events observed by the pamela mission.\BBCQ \APACjournalVolNumPagesThe Astrophysical Journal862297. \PrintBackRefs\CurrentBib
  3. \APACrefYear2013. \APACrefbtitleExtreme space weather: impacts on engineered systems and infrastructure Extreme space weather: impacts on engineered systems and infrastructure. \APACaddressPublisherRoyal Academy of Engineering. \PrintBackRefs\CurrentBib
  4. \APACinsertmetastarCCMC{APACrefauthors}Community Coordinated Modelling Center.  \APACrefYearMonthDay\bibnodate. \APACrefbtitleCCMC. CCMC. \APACrefnotehttps://ccmc.gsfc.nasa.gov \PrintBackRefs\CurrentBib
  5. \APACrefYearMonthDay19915. \BBOQ\APACrefatitleOn cosmic-ray cut-off terminology On cosmic-ray cut-off terminology.\BBCQ \APACjournalVolNumPagesIl Nuovo Cimento C14213-234. {APACrefURL} https://link.springer.com/article/10.1007/BF02509357 {APACrefDOI} 10.1007/BF02509357/METRICS \PrintBackRefs\CurrentBib
  6. \APACinsertmetastarcopeland2017cari{APACrefauthors}Copeland, K.  \APACrefYearMonthDay2017. \BBOQ\APACrefatitleCARI-7A: Development and validation Cari-7a: Development and validation.\BBCQ \APACjournalVolNumPagesRadiation Protection Dosimetry1754419–431. \PrintBackRefs\CurrentBib
  7. \APACrefYearMonthDay2008. \BBOQ\APACrefatitleCosmic radiation exposure of aircraft occupants on simulated high-latitude flights during solar proton events from 1 January 1986 through 1 January 2008 Cosmic radiation exposure of aircraft occupants on simulated high-latitude flights during solar proton events from 1 january 1986 through 1 january 2008.\BBCQ \APACjournalVolNumPagesAdvances in Space Research4261008–1029. \PrintBackRefs\CurrentBib
  8. \APACrefYearMonthDay1997. \BBOQ\APACrefatitleThe October 22, 1989, solar cosmic ray enhancement: An analysis of the anisotropy and spectral characteristics The october 22, 1989, solar cosmic ray enhancement: An analysis of the anisotropy and spectral characteristics.\BBCQ \APACjournalVolNumPagesJournal of Geophysical Research: Space Physics102A1124237–24248. \PrintBackRefs\CurrentBib
  9. \APACinsertmetastarAsympDirsCalculator{APACrefauthors}Davis, C\BPBIS\BPBIW.  \APACrefYearMonthDay2024\BCnt1\APACmonth04. \BBOQ\APACrefatitleAsymptoticDirectionsCalculator-public AsymptoticDirectionsCalculator-public\BBCQ [\bibcomputersoftware]. {APACrefURL} https://github.com/ssc-maire/AsymptoticDirectionsCalculator-public \APACrefnoteversion 1.0.9 {APACrefDOI} 10.5281/zenodo.10992606 \PrintBackRefs\CurrentBib
  10. \APACinsertmetastarcosraymodifiediso{APACrefauthors}Davis, C\BPBIS\BPBIW.  \APACrefYearMonthDay2024\BCnt2\APACmonth04. \BBOQ\APACrefatitleCosRayModifiedISO CosRayModifiedISO\BBCQ [\bibcomputersoftware]. {APACrefURL} https://github.com/ssc-maire/CosRayModifiedISO \APACrefnoteversion 1.2.4 {APACrefDOI} 10.5281/zenodo.10992395 \PrintBackRefs\CurrentBib
  11. \APACinsertmetastarParticleRigidityCalculationTools{APACrefauthors}Davis, C\BPBIS\BPBIW.  \APACrefYearMonthDay2024\BCnt3\APACmonth04. \BBOQ\APACrefatitleParticleRigidityCalculationTools ParticleRigidityCalculationTools\BBCQ [\bibcomputersoftware]. {APACrefURL} https://github.com/ChrisSWDavis/ParticleRigidityCalculationTools \APACrefnoteversion 1.5.7 {APACrefDOI} 10.5281/zenodo.10992232 \PrintBackRefs\CurrentBib
  12. \APACrefYearMonthDay2024\APACmonth04. \BBOQ\APACrefatitleDoseAndFluxCalculator DoseAndFluxCalculator\BBCQ [\bibcomputersoftware]. {APACrefURL} https://github.com/ssc-maire/DoseAndFluxCalculator \APACrefnoteversion 1.0.4 {APACrefDOI} 10.5281/zenodo.10992476 \PrintBackRefs\CurrentBib
  13. \APACrefYearMonthDay2024\APACmonth04. \BBOQ\APACrefatitleAniMAIRE AniMAIRE\BBCQ [\bibcomputersoftware]. {APACrefURL} https://github.com/ssc-maire/AniMAIRE-public \APACrefnoteversion 1.1.5 {APACrefDOI} 10.5281/zenodo.10992643 \PrintBackRefs\CurrentBib
  14. \APACinsertmetastarPLANETOCOSMICS{APACrefauthors}Desorgher, L.  \APACrefYearMonthDay\bibnodate. \APACrefbtitlePLANETOCOSMICS. Planetocosmics. {APACrefURL} http://cosray.unibe.ch/∼laurent/planetocosmics/ \PrintBackRefs\CurrentBib
  15. \APACinsertmetastardesorgher2004magnetocosmics{APACrefauthors}Desorgher, L.  \APACrefYearMonthDay2004. \BBOQ\APACrefatitleMAGNETOCOSMICS Software User Manual Magnetocosmics software user manual\BBCQ [\bibcomputersoftwaremanual]. \APACrefnotePhysikalisches Institut University of Bern, http://reat.space. qinetiq.com/septimess/magcos/magnetocosmics_sum.pdf, Bern \PrintBackRefs\CurrentBib
  16. \APACinsertmetastarMAGNETOCOSMICS{APACrefauthors}Desorgher, L.  \APACrefYearMonthDay2006\APACmonth09. \BBOQ\APACrefatitleMAGNETOCOSMICS MAGNETOCOSMICS\BBCQ [\bibcomputersoftware]. {APACrefURL} http://cosray.unibe.ch/~laurent/magnetocosmics/ \APACrefnoteversion 2.0 \PrintBackRefs\CurrentBib
  17. \APACrefYearMonthDay2006. \BBOQ\APACrefatitleThe planetocosmics geant4 application The planetocosmics geant4 application.\BBCQ \BIn \APACrefbtitle36th COSPAR Scientific Assembly 36th cospar scientific assembly (\BVOL 36, \BPG 2361). \PrintBackRefs\CurrentBib
  18. \APACrefYearMonthDay2017. \BBOQ\APACrefatitleExtreme atmospheric radiation environments and single event effects Extreme atmospheric radiation environments and single event effects.\BBCQ \APACjournalVolNumPagesIEEE Transactions on Nuclear Science651432–438. \PrintBackRefs\CurrentBib
  19. \APACrefYearMonthDay2007. \BBOQ\APACrefatitleSolar particle events in the QinetiQ atmospheric radiation model Solar particle events in the qinetiq atmospheric radiation model.\BBCQ \APACjournalVolNumPagesIEEE Transactions on Nuclear Science5441071–1075. \PrintBackRefs\CurrentBib
  20. \APACrefYearMonthDay1989. \BBOQ\APACrefatitleMeasurements of the SEU environment in the upper atmosphere Measurements of the seu environment in the upper atmosphere.\BBCQ \APACjournalVolNumPagesIEEE Transactions on Nuclear Science3662275–2280. \PrintBackRefs\CurrentBib
  21. \APACrefYearMonthDay1990. \BBOQ\APACrefatitleMeasurements of solar flare enhancements to the single event upset environment in the upper atmosphere (avionics) Measurements of solar flare enhancements to the single event upset environment in the upper atmosphere (avionics).\BBCQ \APACjournalVolNumPagesIEEE Transactions on Nuclear Science3761929–1937. \PrintBackRefs\CurrentBib
  22. \APACinsertmetastarNoM{APACrefauthors}European Space Agency.  \APACrefYearMonthDay\bibnodate. \APACrefbtitleESA Network of Models. ESA Network of Models. \APACrefnotehttps://nom.esa.int/ \PrintBackRefs\CurrentBib
  23. \APACrefYearMonthDay2022. \BBOQ\APACrefatitleA New Model for Nowcasting the Aviation Radiation Environment With Comparisons to In Situ Measurements During GLEs A new model for nowcasting the aviation radiation environment with comparisons to in situ measurements during gles.\BBCQ \APACjournalVolNumPagesSpace Weather208e2022SW003155. \PrintBackRefs\CurrentBib
  24. \APACrefYearMonthDay2016. \BBOQ\APACrefatitleNew data and modelling for single event effects in the stratospheric radiation environment New data and modelling for single event effects in the stratospheric radiation environment.\BBCQ \APACjournalVolNumPagesIEEE Transactions on Nuclear Science641587–595. \PrintBackRefs\CurrentBib
  25. \APACinsertmetastarkarapetyan2008detection{APACrefauthors}Karapetyan, G.  \APACrefYearMonthDay2008. \BBOQ\APACrefatitleDetection of high energy solar protons during ground level enhancements Detection of high energy solar protons during ground level enhancements.\BBCQ \APACjournalVolNumPagesAstroparticle Physics305234–238. \PrintBackRefs\CurrentBib
  26. \APACrefYearMonthDay2014. \BBOQ\APACrefatitleRadiation dose forecast of WASAVIES during ground-level enhancement Radiation dose forecast of wasavies during ground-level enhancement.\BBCQ \APACjournalVolNumPagesSpace Weather126380–386. \PrintBackRefs\CurrentBib
  27. \APACrefYearMonthDay2003. \BBOQ\APACrefatitleHistory of the solar particle event radiation doses on-board aeroplanes using a semi-empirical model and Concorde measurements History of the solar particle event radiation doses on-board aeroplanes using a semi-empirical model and concorde measurements.\BBCQ \APACjournalVolNumPagesRadiation Protection Dosimetry1043199–210. \PrintBackRefs\CurrentBib
  28. \APACrefYearMonthDay2004. \BBOQ\APACrefatitleSemi-empirical model to calculate potential radiation exposure on board airplane during solar particle events Semi-empirical model to calculate potential radiation exposure on board airplane during solar particle events.\BBCQ \APACjournalVolNumPagesIEEE transactions on plasma science3241468–1477. \PrintBackRefs\CurrentBib
  29. \APACrefYearMonthDay2023. \BBOQ\APACrefatitleA New Open-Source Geomagnetosphere Propagation Tool (OTSO) and Its Applications A new open-source geomagnetosphere propagation tool (otso) and its applications.\BBCQ \APACjournalVolNumPagesJournal of Geophysical Research: Space Physics1283e2022JA031061. \PrintBackRefs\CurrentBib
  30. \APACrefYearMonthDay2009. \BBOQ\APACrefatitleAVIDOS—A software package for European accredited aviation dosimetry Avidos—a software package for european accredited aviation dosimetry.\BBCQ \APACjournalVolNumPagesRadiation Protection Dosimetry1364286–290. \PrintBackRefs\CurrentBib
  31. \APACinsertmetastarMAIREUK{APACrefauthors}Lei, F.  \APACrefYearMonthDay\bibnodate. \APACrefbtitleModels for Atmospheric Ionising Radiation Effects - MAIRE. Models for Atmospheric Ionising Radiation Effects - MAIRE. \APACrefnotehttp://maire.uk/maire/ \PrintBackRefs\CurrentBib
  32. \APACrefYearMonthDay2004. \BBOQ\APACrefatitleAn atmospheric radiation model based on response matrices generated by detailed Monte Carlo simulations of cosmic ray interactions An atmospheric radiation model based on response matrices generated by detailed monte carlo simulations of cosmic ray interactions.\BBCQ \APACjournalVolNumPagesIEEE Transactions on Nuclear Science5163442–3451. \PrintBackRefs\CurrentBib
  33. \APACrefYearMonthDay2005. \BBOQ\APACrefatitleImprovements to and validations of the QinetiQ Atmospheric Radiation Model (QARM) Improvements to and validations of the qinetiq atmospheric radiation model (qarm).\BBCQ \BIn \APACrefbtitle2005 8th European Conference on Radiation and Its Effects on Components and Systems 2005 8th european conference on radiation and its effects on components and systems (\BPGS D3–1). \PrintBackRefs\CurrentBib
  34. \APACrefYearMonthDay2013. \BBOQ\APACrefatitleA ready-to-use galactic cosmic ray model A ready-to-use galactic cosmic ray model.\BBCQ \APACjournalVolNumPagesAdvances in Space Research513329–338. \PrintBackRefs\CurrentBib
  35. \APACrefYearMonthDay2020. \BBOQ\APACrefatitleRadiation in the atmosphere—A hazard to aviation safety? Radiation in the atmosphere—a hazard to aviation safety?\BBCQ \APACjournalVolNumPagesAtmosphere11121358. \PrintBackRefs\CurrentBib
  36. \APACrefYearMonthDay2023. \BBOQ\APACrefatitleNAIRAS Model Run-On-Request Service at CCMC Nairas model run-on-request service at ccmc.\BBCQ \APACjournalVolNumPagesSpace Weather215e2023SW003473. \PrintBackRefs\CurrentBib
  37. \APACrefYearMonthDay2009. \BBOQ\APACrefatitleDevelopment of nowcast of atmospheric ionizing radiation for aviation safety (nairas) model Development of nowcast of atmospheric ionizing radiation for aviation safety (nairas) model.\BBCQ \BIn \APACrefbtitle1st AIAA Atmospheric and Space Environments Conference 1st aiaa atmospheric and space environments conference (\BPG 3633). \PrintBackRefs\CurrentBib
  38. \APACrefYearMonthDay2013. \APACrefbtitleNAIRAS aircraft radiation model development, dose climatology, and initial validation. Nairas aircraft radiation model development, dose climatology, and initial validation. \APACaddressPublisherWiley Online Library. \PrintBackRefs\CurrentBib
  39. \APACrefYearMonthDay2015. \BBOQ\APACrefatitleComputation of dose rate at flight altitudes during ground level enhancements no. 69, 70 and 71 Computation of dose rate at flight altitudes during ground level enhancements no. 69, 70 and 71.\BBCQ \APACjournalVolNumPagesAdvances in Space Research551354–362. \PrintBackRefs\CurrentBib
  40. \APACrefYearMonthDay2021. \BBOQ\APACrefatitleApplication of the verified neutron monitor yield function for an extended analysis of the GLE# 71 on 17 May 2012 Application of the verified neutron monitor yield function for an extended analysis of the gle# 71 on 17 may 2012.\BBCQ \APACjournalVolNumPagesSpace Weather192e2020SW002626. \PrintBackRefs\CurrentBib
  41. \APACrefYearMonthDay2016. \BBOQ\APACrefatitleAnalysis of the ground-level enhancements on 14 July 2000 and 13 December 2006 using neutron monitor data Analysis of the ground-level enhancements on 14 july 2000 and 13 december 2006 using neutron monitor data.\BBCQ \APACjournalVolNumPagesSolar Physics2911225–1239. \PrintBackRefs\CurrentBib
  42. \APACrefYearMonthDay1993. \BBOQ\APACrefatitleAltitude and latitude variations in avionics SEU and atmospheric neutron flux Altitude and latitude variations in avionics seu and atmospheric neutron flux.\BBCQ \APACjournalVolNumPagesIEEE transactions on Nuclear Science4061484–1490. \PrintBackRefs\CurrentBib
  43. \APACrefYearMonthDay2018. \BBOQ\APACrefatitleReal time and automatic analysis program for WASAVIES: Warning system for aviation exposure to solar energetic particles Real time and automatic analysis program for wasavies: Warning system for aviation exposure to solar energetic particles.\BBCQ \APACjournalVolNumPagesSpace Weather167924–936. \PrintBackRefs\CurrentBib
  44. \APACrefYearMonthDay2012. \BBOQ\APACrefatitleSpace weather and the ground-level solar proton events of the 23rd solar cycle Space weather and the ground-level solar proton events of the 23rd solar cycle.\BBCQ \APACjournalVolNumPagesSpace science reviews1711161–188. \PrintBackRefs\CurrentBib
  45. \APACrefYearMonthDay1993. \BBOQ\APACrefatitleSingle event upset in avionics Single event upset in avionics.\BBCQ \APACjournalVolNumPagesIEEE Transactions on Nuclear Science402120–126. \PrintBackRefs\CurrentBib
  46. \APACrefYearMonthDay2015. \BBOQ\APACrefatitleAdvances in atmospheric radiation measurements and modeling needed to improve air safety Advances in atmospheric radiation measurements and modeling needed to improve air safety.\BBCQ \APACjournalVolNumPagesSpace Weather134202–210. \PrintBackRefs\CurrentBib
  47. \APACinsertmetastartsyganenko1989magnetospheric{APACrefauthors}Tsyganenko, N\BPBIA.  \APACrefYearMonthDay1989. \BBOQ\APACrefatitleA magnetospheric magnetic field model with a warped tail current sheet A magnetospheric magnetic field model with a warped tail current sheet.\BBCQ \APACjournalVolNumPagesPlanetary and Space Science3715–20. \PrintBackRefs\CurrentBib
  48. \APACrefYearMonthDay2015. \BBOQ\APACrefatitleDatabase of ground level enhancements (GLE) of high energy solar proton events Database of ground level enhancements (GLE) of high energy solar proton events.\BBCQ \APACjournalVolNumPagesProceedings of Science, Proc. of 34th ICRC Hague, Netherlands30. \PrintBackRefs\CurrentBib

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