The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission: Exploring the Coupling of Space Weather and Terrestrial Climate

Ian R. Mann; C. M. Cully; R. Fedosejevs; D. K. Milling; G. A. Enno; M. Lipsett; R. E. Zee; B. P. Larouche; R. Rankin; M. G. Connors; K. A. McWilliams; W. E. Ward; R. A. Fiori; L. Olifer; L. Ozeke; R. A. Marshall; D. Cullen; D. Barona; A. D. Howarth; A. W. Yau

doi:10.1117/12.3062070

The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission: Exploring the Coupling of Space Weather and Terrestrial Climate

Ian R. Mann, C. M. Cully, R. Fedosejevs, D. K. Milling, G. A. Enno, M. Lipsett, R. E. Zee, B. P. Larouche, R. Rankin, M. G. Connors, K. A. McWilliams, W. E. Ward, R. A. Fiori, L. Olifer, L. Ozeke, R. A. Marshall, D. Cullen, D. Barona, A. D. Howarth, A. W. Yau

Centre for Science

Research output: Chapter in Book/Report/Conference proceeding › Published Conference contribution › peer-review

Abstract

The RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) is a low-Earth orbiting Canadian small satellite mission investigating the transport of space radiation into the atmosphere, and its impact on Earth’s climate. Scheduled for launch in late 2026, the mission will launch into a polar orbit with an integrated payload comprising two back-to-back look direction High Energy Particle (RADHEPT) telescopes, an X-Ray Imager (XRI) to remote sense energetic particle precipitation using back-scattered Bremsstrahlung X-rays, and a boom mounted FluxGate Magnetometer (FGM) and Search Coil Magnetometer (SCM). Using an innovative Thomson spin-stabilized configuration, the satellite will sample the pitch angle distributions in the spin-plane twice per spin. The back-to-back RADHEPT look directions allow for a contemporaneous view of the down-going and back-scattered up-going electrons, at the same time the XRI remote-senses the related Bremsstrahlung, and the magnetometers provide in-situ magnetic signatures of a range of plasma waves. The key measurement of the pitch angle resolved energetic electron precipitation (EEP) and related back-scatter, including a resolved loss cone, will allow a detailed assessment of the energetic particle energy input to the atmosphere. Measurements of EEP, in addition to measurements of solar energetic particle (SEP) precipitation, will represent a critical data set for assessing the role of space radiation in the climate system, for example through the catalytic destruction of ozone in the middle atmosphere by NOx and HOx. Accurately quantifying the impacts of this space radiation on climate requires accurate and loss cone-resolved characterization of the flux of these precipitating energetic particles for inclusion into whole atmosphere models. The RADICALS explorer will also enable research into potentially catastrophic space-weather radiation effects on satellite infrastructure, and assess impacts on space weather-related interruptions to high frequency radio communications including in relation to aircraft operations in polar regions. Here we provide an overview of the innovative RADICALS mission development. We further highlight additional partnership opportunities for cube- and micro-satellite missions, and which together with the RADICALS could form a more powerful mini-constellation exploring the space weather-climate system.

Original language	English
Title of host publication	Small Satellites Systems and Services Symposium, 4S 2024
Editors	Palma de Mallorca
ISBN (Electronic)	9781510688940
DOIs	https://doi.org/10.1117/12.3062070
Publication status	Published - 2025
Event	2024 Small Satellites Systems and Services Symposium, 4S 2024 - Palma de Mallorca, Spain Duration: 27 May 2024 → 31 May 2024

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	13546
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	2024 Small Satellites Systems and Services Symposium, 4S 2024
Country/Territory	Spain
City	Palma de Mallorca
Period	27/05/24 → 31/05/24

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1117/12.3062070

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Mann, I. R., Cully, C. M., Fedosejevs, R., Milling, D. K., Enno, G. A., Lipsett, M., Zee, R. E., Larouche, B. P., Rankin, R., Connors, M. G., McWilliams, K. A., Ward, W. E., Fiori, R. A., Olifer, L., Ozeke, L., Marshall, R. A., Cullen, D., Barona, D., Howarth, A. D., & Yau, A. W. (2025). The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission: Exploring the Coupling of Space Weather and Terrestrial Climate. In P. de Mallorca (Ed.), Small Satellites Systems and Services Symposium, 4S 2024 Article 135462J (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13546). https://doi.org/10.1117/12.3062070

Mann, Ian R. ; Cully, C. M. ; Fedosejevs, R. et al. / The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission : Exploring the Coupling of Space Weather and Terrestrial Climate. Small Satellites Systems and Services Symposium, 4S 2024. editor / Palma de Mallorca. 2025. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{416149edf3f34320965bf108e71275cf,

title = "The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission: Exploring the Coupling of Space Weather and Terrestrial Climate",

abstract = "The RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) is a low-Earth orbiting Canadian small satellite mission investigating the transport of space radiation into the atmosphere, and its impact on Earth{\textquoteright}s climate. Scheduled for launch in late 2026, the mission will launch into a polar orbit with an integrated payload comprising two back-to-back look direction High Energy Particle (RADHEPT) telescopes, an X-Ray Imager (XRI) to remote sense energetic particle precipitation using back-scattered Bremsstrahlung X-rays, and a boom mounted FluxGate Magnetometer (FGM) and Search Coil Magnetometer (SCM). Using an innovative Thomson spin-stabilized configuration, the satellite will sample the pitch angle distributions in the spin-plane twice per spin. The back-to-back RADHEPT look directions allow for a contemporaneous view of the down-going and back-scattered up-going electrons, at the same time the XRI remote-senses the related Bremsstrahlung, and the magnetometers provide in-situ magnetic signatures of a range of plasma waves. The key measurement of the pitch angle resolved energetic electron precipitation (EEP) and related back-scatter, including a resolved loss cone, will allow a detailed assessment of the energetic particle energy input to the atmosphere. Measurements of EEP, in addition to measurements of solar energetic particle (SEP) precipitation, will represent a critical data set for assessing the role of space radiation in the climate system, for example through the catalytic destruction of ozone in the middle atmosphere by NOx and HOx. Accurately quantifying the impacts of this space radiation on climate requires accurate and loss cone-resolved characterization of the flux of these precipitating energetic particles for inclusion into whole atmosphere models. The RADICALS explorer will also enable research into potentially catastrophic space-weather radiation effects on satellite infrastructure, and assess impacts on space weather-related interruptions to high frequency radio communications including in relation to aircraft operations in polar regions. Here we provide an overview of the innovative RADICALS mission development. We further highlight additional partnership opportunities for cube- and micro-satellite missions, and which together with the RADICALS could form a more powerful mini-constellation exploring the space weather-climate system.",

author = "Mann, \{Ian R.\} and Cully, \{C. M.\} and R. Fedosejevs and Milling, \{D. K.\} and Enno, \{G. A.\} and M. Lipsett and Zee, \{R. E.\} and Larouche, \{B. P.\} and R. Rankin and Connors, \{M. G.\} and McWilliams, \{K. A.\} and Ward, \{W. E.\} and Fiori, \{R. A.\} and L. Olifer and L. Ozeke and Marshall, \{R. A.\} and D. Cullen and D. Barona and Howarth, \{A. D.\} and Yau, \{A. W.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors.; 2024 Small Satellites Systems and Services Symposium, 4S 2024 ; Conference date: 27-05-2024 Through 31-05-2024",

year = "2025",

doi = "10.1117/12.3062070",

language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

editor = "\{de Mallorca\}, Palma",

booktitle = "Small Satellites Systems and Services Symposium, 4S 2024",

}

Mann, IR, Cully, CM, Fedosejevs, R, Milling, DK, Enno, GA, Lipsett, M, Zee, RE, Larouche, BP, Rankin, R, Connors, MG, McWilliams, KA, Ward, WE, Fiori, RA, Olifer, L, Ozeke, L, Marshall, RA, Cullen, D, Barona, D, Howarth, AD & Yau, AW 2025, The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission: Exploring the Coupling of Space Weather and Terrestrial Climate. in P de Mallorca (ed.), Small Satellites Systems and Services Symposium, 4S 2024., 135462J, Proceedings of SPIE - The International Society for Optical Engineering, vol. 13546, 2024 Small Satellites Systems and Services Symposium, 4S 2024, Palma de Mallorca, Spain, 27/05/24. https://doi.org/10.1117/12.3062070

The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission: Exploring the Coupling of Space Weather and Terrestrial Climate. / Mann, Ian R.; Cully, C. M.; Fedosejevs, R. et al.
Small Satellites Systems and Services Symposium, 4S 2024. ed. / Palma de Mallorca. 2025. 135462J (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13546).

Research output: Chapter in Book/Report/Conference proceeding › Published Conference contribution › peer-review

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AU - Connors, M. G.

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AU - Fiori, R. A.

AU - Olifer, L.

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N2 - The RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) is a low-Earth orbiting Canadian small satellite mission investigating the transport of space radiation into the atmosphere, and its impact on Earth’s climate. Scheduled for launch in late 2026, the mission will launch into a polar orbit with an integrated payload comprising two back-to-back look direction High Energy Particle (RADHEPT) telescopes, an X-Ray Imager (XRI) to remote sense energetic particle precipitation using back-scattered Bremsstrahlung X-rays, and a boom mounted FluxGate Magnetometer (FGM) and Search Coil Magnetometer (SCM). Using an innovative Thomson spin-stabilized configuration, the satellite will sample the pitch angle distributions in the spin-plane twice per spin. The back-to-back RADHEPT look directions allow for a contemporaneous view of the down-going and back-scattered up-going electrons, at the same time the XRI remote-senses the related Bremsstrahlung, and the magnetometers provide in-situ magnetic signatures of a range of plasma waves. The key measurement of the pitch angle resolved energetic electron precipitation (EEP) and related back-scatter, including a resolved loss cone, will allow a detailed assessment of the energetic particle energy input to the atmosphere. Measurements of EEP, in addition to measurements of solar energetic particle (SEP) precipitation, will represent a critical data set for assessing the role of space radiation in the climate system, for example through the catalytic destruction of ozone in the middle atmosphere by NOx and HOx. Accurately quantifying the impacts of this space radiation on climate requires accurate and loss cone-resolved characterization of the flux of these precipitating energetic particles for inclusion into whole atmosphere models. The RADICALS explorer will also enable research into potentially catastrophic space-weather radiation effects on satellite infrastructure, and assess impacts on space weather-related interruptions to high frequency radio communications including in relation to aircraft operations in polar regions. Here we provide an overview of the innovative RADICALS mission development. We further highlight additional partnership opportunities for cube- and micro-satellite missions, and which together with the RADICALS could form a more powerful mini-constellation exploring the space weather-climate system.

AB - The RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) is a low-Earth orbiting Canadian small satellite mission investigating the transport of space radiation into the atmosphere, and its impact on Earth’s climate. Scheduled for launch in late 2026, the mission will launch into a polar orbit with an integrated payload comprising two back-to-back look direction High Energy Particle (RADHEPT) telescopes, an X-Ray Imager (XRI) to remote sense energetic particle precipitation using back-scattered Bremsstrahlung X-rays, and a boom mounted FluxGate Magnetometer (FGM) and Search Coil Magnetometer (SCM). Using an innovative Thomson spin-stabilized configuration, the satellite will sample the pitch angle distributions in the spin-plane twice per spin. The back-to-back RADHEPT look directions allow for a contemporaneous view of the down-going and back-scattered up-going electrons, at the same time the XRI remote-senses the related Bremsstrahlung, and the magnetometers provide in-situ magnetic signatures of a range of plasma waves. The key measurement of the pitch angle resolved energetic electron precipitation (EEP) and related back-scatter, including a resolved loss cone, will allow a detailed assessment of the energetic particle energy input to the atmosphere. Measurements of EEP, in addition to measurements of solar energetic particle (SEP) precipitation, will represent a critical data set for assessing the role of space radiation in the climate system, for example through the catalytic destruction of ozone in the middle atmosphere by NOx and HOx. Accurately quantifying the impacts of this space radiation on climate requires accurate and loss cone-resolved characterization of the flux of these precipitating energetic particles for inclusion into whole atmosphere models. The RADICALS explorer will also enable research into potentially catastrophic space-weather radiation effects on satellite infrastructure, and assess impacts on space weather-related interruptions to high frequency radio communications including in relation to aircraft operations in polar regions. Here we provide an overview of the innovative RADICALS mission development. We further highlight additional partnership opportunities for cube- and micro-satellite missions, and which together with the RADICALS could form a more powerful mini-constellation exploring the space weather-climate system.

UR - https://www.scopus.com/pages/publications/105002242819

U2 - 10.1117/12.3062070

DO - 10.1117/12.3062070

M3 - Published Conference contribution

AN - SCOPUS:105002242819

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Small Satellites Systems and Services Symposium, 4S 2024

A2 - de Mallorca, Palma

Y2 - 27 May 2024 through 31 May 2024

ER -

Mann IR, Cully CM, Fedosejevs R, Milling DK, Enno GA, Lipsett M et al. The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission: Exploring the Coupling of Space Weather and Terrestrial Climate. In de Mallorca P, editor, Small Satellites Systems and Services Symposium, 4S 2024. 2025. 135462J. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.3062070

The Canadian RADiation Impacts on Climate and Atmospheric Loss Satellite (RADICALS) Mission: Exploring the Coupling of Space Weather and Terrestrial Climate

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