Explaining circumsolar Solar Energetic Particle events
Lead Research Organisation:
University of Lancashire
Department Name: Jeremiah Horrocks Institute
Abstract
Solar Energetic Particles (SEPs) are accelerated during large eruptions at the Sun and travel through the interplanetary medium to reach near-Earth space. They can be detected by instrumentation on spacecraft. SEP data and models are used to understand the physics of particle acceleration and propagation in space. When their flux is very large, SEPs pose a risk to satellites and humans in space: for this reason they are an important component of Space Weather.
A new era of SEP research started with the launch of Parker Solar Probe (PSP, launch 2018) and Solar Orbiter (SolO, launch 2020): together with STEREO A and spacecraft near Earth and other planets, they form a fleet of missions often located at widely separated points in space, providing the opportunity to map the spatial distribution of SEPs.
Since 2021, data from this fleet have shown that circumsolar events, where SEPs fill the entire 360 degrees in longitude around the Sun, are not rare, as previously thought, but a common occurrence.
This project focusses on the question: How are SEPs able to fill wide regions of space, including areas on the opposite side of the Sun with respect to the location of the solar eruption that accelerated them? In classic SEP models, particles are expected to remain tied to the magnetic field of interplanetary space, and propagate inefficiently in the direction perpendicular to the field, making it impossible for them to reach locations on the opposite side of the Sun compared to where they were accelerated.
In this project, models of SEP propagation will be developed that are able to describe a variety of mechanisms for propagation across the magnetic field. These include the effects of turbulence in space, of a wide region called the heliospheric current sheet, where the direction of the magnetic field in the heliosphere reverses, and of the rotation of the Sun. The possibility that CMEs are accelerated over wide regions of space in association with coronal mass ejections will also be considered. Results from the models will be compared with spacecraft measurements from PSP, SolO and near-Earth spacecraft to test different propagation scenarios.
A new era of SEP research started with the launch of Parker Solar Probe (PSP, launch 2018) and Solar Orbiter (SolO, launch 2020): together with STEREO A and spacecraft near Earth and other planets, they form a fleet of missions often located at widely separated points in space, providing the opportunity to map the spatial distribution of SEPs.
Since 2021, data from this fleet have shown that circumsolar events, where SEPs fill the entire 360 degrees in longitude around the Sun, are not rare, as previously thought, but a common occurrence.
This project focusses on the question: How are SEPs able to fill wide regions of space, including areas on the opposite side of the Sun with respect to the location of the solar eruption that accelerated them? In classic SEP models, particles are expected to remain tied to the magnetic field of interplanetary space, and propagate inefficiently in the direction perpendicular to the field, making it impossible for them to reach locations on the opposite side of the Sun compared to where they were accelerated.
In this project, models of SEP propagation will be developed that are able to describe a variety of mechanisms for propagation across the magnetic field. These include the effects of turbulence in space, of a wide region called the heliospheric current sheet, where the direction of the magnetic field in the heliosphere reverses, and of the rotation of the Sun. The possibility that CMEs are accelerated over wide regions of space in association with coronal mass ejections will also be considered. Results from the models will be compared with spacecraft measurements from PSP, SolO and near-Earth spacecraft to test different propagation scenarios.
Organisations
- University of Lancashire (Lead Research Organisation)
- National Aeronautics and Space Administration (NASA) (Collaboration)
- University of Oslo (Collaboration)
- North-West University (Collaboration)
- University of Alabama in Huntsville (Collaboration)
- University of Waikato (Collaboration)
- University of Calabria (Collaboration)
- Northumbria University (Collaboration)
- International Space Science Institute (ISSI) (Collaboration)
- Meteorological Office UK (Collaboration)
- Mahidol University (Collaboration)
- Rutherford Appleton Laboratory (Collaboration)
- UNIVERSITY OF READING (Collaboration)
- University of St Andrews (Collaboration)
- Lund University (Collaboration)
- Ruhr University Bochum (Collaboration)
- Princeton University (Collaboration)
- UNIVERSITY COLLEGE LONDON (Collaboration)
- University of Helsinki (Collaboration)
- University of Delaware (Collaboration)
- European Space Agency (Collaboration)
- University of Graz (Collaboration)
- University of Göttingen (Collaboration)
People |
ORCID iD |
| Silvia Dalla (Principal Investigator) | |
| Timo Laitinen (Researcher) |
Publications
RodrĂguez-GarcĂa L
(2025)
Solar energetic particles injected inside and outside a magnetic cloud The widespread solar energetic particle event on 2022 January 20
in Astronomy & Astrophysics
Laitinen T
(2025)
Interplay of Large-scale Drift and Turbulence in the Heliospheric Propagation of Solar Energetic Particles
in The Astrophysical Journal
Hyndman R
(2025)
Multi-spacecraft observations of the decay phase of solar energetic particle events
in Astronomy & Astrophysics
| Title | Simulation data for paper "Interplay of large-scale drift and turbulence in the heliospheric propagation of solar energetic particles" |
| Description | The datasets contains the data analysed in paper "Interplay of large-scale drift and turbulence in the heliospheric propagation of solar energetic particles" by T. Laitinen and S. Dalla. The file Simulation_sets.zip contains files Set_N_AAAA.csv, where N is an integer from 1 to 8, and AAAA is either "scat" or "turb". These files contain simulation data for 8 different simulation sets with two different types of simulations in each. The simulation sets are described in table1.csv, which contains the data in Table 1 of the paper. Further results are given in table2.csv, which contains the data in Table 2 of the paper Set_N_AAAA.csv: - t0: time of the first crossing of 1-au sphere (s) - dt: time between the last and first crossing of the 1-au sphere (s) - theta0: colatitude of the first crossing of 1-au sphere (degrees) - dtheta: difference between the colatitudes of the last and first crossings of 1-au sphere (degrees) table1.csv: - Set: Simulation set identifier (string) - E MeV: proton energy (MeV) - Pol: Unipolar solar magnetic polarity (B+: outwards and B-: inwards pointing field) - vd_theor: Drift velocity calculated at 1 au from theory (km/s) - Sim: Simulation identifier (scat or turb) - Lambda: Parallel mean free path in scat simulations (au) - dB2B2_1au: Relative turbulence variance at 1 au - vd_FL: Median drift velocity obtained from medians of each turbulence realisation drift velocities (km/s) - vd_FL_std: standard deviation of the medians of each turbulence realisation drift velocities (km/s) - table2.csv: - Set: Simulation set identifier (string) - rL_lambda_s: ratio of the particle's Larmor radius and the breakpoint scale of the slab component of the turbulence - fs_sim: Drift reduction factor obtained from simulations - fs_sim_std: Standard deviation of drift reduction factor obtained from simulations - fs_BAM: Drift reduction factor obtained from theory of Bieber & Matthaeus (1997) - fs_Eng2017: Drift reduction factor obtained from theory of Engelbrecht et al. (2017) |
| Type Of Material | Database/Collection of data |
| Year Produced | 2024 |
| Provided To Others? | Yes |
| Impact | This dataset was developed for evaluating the interplay between large-scale solar energetic particle (SEP) drifts and turbulence as the particles propagate in heliosphere. The dataset was created by use of full-orbit simulations of SEPs with a novel heliospheric turbulence model. Results show that while the heliospheric turbulence can reduce drifts, the reduction is significantly weaker than that suggested by theoretical work. |
| URL | https://zenodo.org/doi/10.5281/zenodo.14284454 |
| Title | Simulation data for paper "Interplay of large-scale drift and turbulence in the heliospheric propagation of solar energetic particles" |
| Description | The datasets contains the data analysed in paper "Interplay of large-scale drift and turbulence in the heliospheric propagation of solar energetic particles" by T. Laitinen and S. Dalla. The file Simulation_sets.zip contains files Set_N_AAAA.csv, where N is an integer from 1 to 8, and AAAA is either "scat" or "turb". These files contain simulation data for 8 different simulation sets with two different types of simulations in each. The simulation sets are described in table1.csv, which contains the data in Table 1 of the paper. Further results are given in table2.csv, which contains the data in Table 2 of the paper Set_N_AAAA.csv: - t0: time of the first crossing of 1-au sphere (s) - dt: time between the last and first crossing of the 1-au sphere (s) - theta0: colatitude of the first crossing of 1-au sphere (degrees) - dtheta: difference between the colatitudes of the last and first crossings of 1-au sphere (degrees) table1.csv: - Set: Simulation set identifier (string) - E MeV: proton energy (MeV) - Pol: Unipolar solar magnetic polarity (B+: outwards and B-: inwards pointing field) - vd_theor: Drift velocity calculated at 1 au from theory (km/s) - Sim: Simulation identifier (scat or turb) - Lambda: Parallel mean free path in scat simulations (au) - dB2B2_1au: Relative turbulence variance at 1 au - vd_FL: Median drift velocity obtained from medians of each turbulence realisation drift velocities (km/s) - vd_FL_std: standard deviation of the medians of each turbulence realisation drift velocities (km/s) - table2.csv: - Set: Simulation set identifier (string) - rL_lambda_s: ratio of the particle's Larmor radius and the breakpoint scale of the slab component of the turbulence - fs_sim: Drift reduction factor obtained from simulations - fs_sim_std: Standard deviation of drift reduction factor obtained from simulations - fs_BAM: Drift reduction factor obtained from theory of Bieber & Matthaeus (1997) - fs_Eng2017: Drift reduction factor obtained from theory of Engelbrecht et al. (2017) |
| Type Of Material | Database/Collection of data |
| Year Produced | 2024 |
| Provided To Others? | Yes |
| URL | https://zenodo.org/doi/10.5281/zenodo.14284455 |
| Description | Dr Laura Rodriguez Garcia, ESA Research Fellow, ESA/ESAC (SCI-EF) |
| Organisation | European Space Agency |
| Department | European Space Astronomy Centre (ESAC) |
| Country | Spain |
| Sector | Public |
| PI Contribution | Contribution to research paper led by the collaborator |
| Collaborator Contribution | Dr. Rodriguez Garcia led a paper on an SEP event that has recently been published. Currently she is a co-author in a manuscript by Prof. Dalla where I am also a co-author. |
| Impact | Astronomy and Astrophysics article, published 4 February 2025, with doi: 10.1051/0004-6361/202452158 |
| Start Year | 2023 |
| Description | Dr Raimund Muescheler, Dr Konstantin Herbst, Prof Mathew Owens |
| Organisation | Lund University |
| Country | Sweden |
| Sector | Academic/University |
| PI Contribution | Investigation of relativistic proton propagation for the interpretation of solar-associated spikes in cosmogenic radionuclides. |
| Collaborator Contribution | Analysis of cosmogenic radionuclides data, modelling of the heliospheric magnetic field. |
| Impact | Work is currently in progress. |
| Start Year | 2024 |
| Description | Dr Raimund Muescheler, Dr Konstantin Herbst, Prof Mathew Owens |
| Organisation | University of Oslo |
| Country | Norway |
| Sector | Academic/University |
| PI Contribution | Investigation of relativistic proton propagation for the interpretation of solar-associated spikes in cosmogenic radionuclides. |
| Collaborator Contribution | Analysis of cosmogenic radionuclides data, modelling of the heliospheric magnetic field. |
| Impact | Work is currently in progress. |
| Start Year | 2024 |
| Description | Dr Raimund Muescheler, Dr Konstantin Herbst, Prof Mathew Owens |
| Organisation | University of Reading |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Investigation of relativistic proton propagation for the interpretation of solar-associated spikes in cosmogenic radionuclides. |
| Collaborator Contribution | Analysis of cosmogenic radionuclides data, modelling of the heliospheric magnetic field. |
| Impact | Work is currently in progress. |
| Start Year | 2024 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | International Space Science Institute (ISSI) |
| Country | Switzerland |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | Mahidol University |
| Country | Thailand |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | National Aeronautics and Space Administration (NASA) |
| Department | Goddard Space Flight Center |
| Country | United States |
| Sector | Public |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | North-West University |
| Country | South Africa |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | Northumbria University |
| Department | Department of Mathematics, Physics and Electrical Engineering |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | Princeton University |
| Department | Department of Astrophysical Sciences |
| Country | United States |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | Ruhr University Bochum |
| Department | Faculty of Physics and Astronomy |
| Country | Germany |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | University of Alabama in Huntsville |
| Country | United States |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | University of Calabria |
| Country | Italy |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | University of Delaware |
| Country | United States |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | ISSI International Team 608, Energetic Particle Transport in Space Plasma Turbulence |
| Organisation | University of Waikato |
| Country | New Zealand |
| Sector | Academic/University |
| PI Contribution | Contribution to the first unsuccessful ISSI International Team Call P roposal in 2023 and the successful proposal in 2024. The proposal was approved in June 2024, with first in-person meeting in March 2025. |
| Collaborator Contribution | Contribution to the successful ISSI International Team Call Proposal, lead by Frederic Effenberger (Germany) and Eugene Engelbrecht (South Africa) |
| Impact | Currently the only output is the successful proposal, and the plans for forthcoming meeting. |
| Start Year | 2023 |
| Description | Use of L5 Data in CME Propagation Models. P3-SWE-IV. |
| Organisation | Meteorological Office UK |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Proposal for an ESA-funded project for investigating use of a spacecraft at L5 to forecast space weather efffects due to coronal mass ejections. The project was approved, with RAL as lead applicant and the others as subcontractors. The subcontracts were projected to start April 2021, but due to partly Covid-related delays , the project started only in October 2022, and is currently projected to end 1 June 2023. Dr. Laitinen is the PI of the UCLan subcontract, and supervises the project subproject, which is being delivered by Dr. Bill Swalwell. |
| Collaborator Contribution | The partners provided modelling and observational data on coronal mass ejections observed by STEREO spacecraft. The UCLan group then utilised this data in analysing how inclusion of observations of the CME at Earth and L5 affect the forecasting of solar energetic particle fluxes at Earth. |
| Impact | Outputs are anticipated in terms of reports from first-second quarter of 2023. Publications are anticipated. |
| Start Year | 2019 |
| Description | Use of L5 Data in CME Propagation Models. P3-SWE-IV. |
| Organisation | Rutherford Appleton Laboratory |
| Department | RAL Space |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Proposal for an ESA-funded project for investigating use of a spacecraft at L5 to forecast space weather efffects due to coronal mass ejections. The project was approved, with RAL as lead applicant and the others as subcontractors. The subcontracts were projected to start April 2021, but due to partly Covid-related delays , the project started only in October 2022, and is currently projected to end 1 June 2023. Dr. Laitinen is the PI of the UCLan subcontract, and supervises the project subproject, which is being delivered by Dr. Bill Swalwell. |
| Collaborator Contribution | The partners provided modelling and observational data on coronal mass ejections observed by STEREO spacecraft. The UCLan group then utilised this data in analysing how inclusion of observations of the CME at Earth and L5 affect the forecasting of solar energetic particle fluxes at Earth. |
| Impact | Outputs are anticipated in terms of reports from first-second quarter of 2023. Publications are anticipated. |
| Start Year | 2019 |
| Description | Use of L5 Data in CME Propagation Models. P3-SWE-IV. |
| Organisation | University College London |
| Department | Department of Space and Climate Physics (MSSL) |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Proposal for an ESA-funded project for investigating use of a spacecraft at L5 to forecast space weather efffects due to coronal mass ejections. The project was approved, with RAL as lead applicant and the others as subcontractors. The subcontracts were projected to start April 2021, but due to partly Covid-related delays , the project started only in October 2022, and is currently projected to end 1 June 2023. Dr. Laitinen is the PI of the UCLan subcontract, and supervises the project subproject, which is being delivered by Dr. Bill Swalwell. |
| Collaborator Contribution | The partners provided modelling and observational data on coronal mass ejections observed by STEREO spacecraft. The UCLan group then utilised this data in analysing how inclusion of observations of the CME at Earth and L5 affect the forecasting of solar energetic particle fluxes at Earth. |
| Impact | Outputs are anticipated in terms of reports from first-second quarter of 2023. Publications are anticipated. |
| Start Year | 2019 |
| Description | Use of L5 Data in CME Propagation Models. P3-SWE-IV. |
| Organisation | University of Graz |
| Country | Austria |
| Sector | Academic/University |
| PI Contribution | Proposal for an ESA-funded project for investigating use of a spacecraft at L5 to forecast space weather efffects due to coronal mass ejections. The project was approved, with RAL as lead applicant and the others as subcontractors. The subcontracts were projected to start April 2021, but due to partly Covid-related delays , the project started only in October 2022, and is currently projected to end 1 June 2023. Dr. Laitinen is the PI of the UCLan subcontract, and supervises the project subproject, which is being delivered by Dr. Bill Swalwell. |
| Collaborator Contribution | The partners provided modelling and observational data on coronal mass ejections observed by STEREO spacecraft. The UCLan group then utilised this data in analysing how inclusion of observations of the CME at Earth and L5 affect the forecasting of solar energetic particle fluxes at Earth. |
| Impact | Outputs are anticipated in terms of reports from first-second quarter of 2023. Publications are anticipated. |
| Start Year | 2019 |
| Description | Use of L5 Data in CME Propagation Models. P3-SWE-IV. |
| Organisation | University of Göttingen |
| Country | Germany |
| Sector | Academic/University |
| PI Contribution | Proposal for an ESA-funded project for investigating use of a spacecraft at L5 to forecast space weather efffects due to coronal mass ejections. The project was approved, with RAL as lead applicant and the others as subcontractors. The subcontracts were projected to start April 2021, but due to partly Covid-related delays , the project started only in October 2022, and is currently projected to end 1 June 2023. Dr. Laitinen is the PI of the UCLan subcontract, and supervises the project subproject, which is being delivered by Dr. Bill Swalwell. |
| Collaborator Contribution | The partners provided modelling and observational data on coronal mass ejections observed by STEREO spacecraft. The UCLan group then utilised this data in analysing how inclusion of observations of the CME at Earth and L5 affect the forecasting of solar energetic particle fluxes at Earth. |
| Impact | Outputs are anticipated in terms of reports from first-second quarter of 2023. Publications are anticipated. |
| Start Year | 2019 |
| Description | Use of L5 Data in CME Propagation Models. P3-SWE-IV. |
| Organisation | University of Helsinki |
| Country | Finland |
| Sector | Academic/University |
| PI Contribution | Proposal for an ESA-funded project for investigating use of a spacecraft at L5 to forecast space weather efffects due to coronal mass ejections. The project was approved, with RAL as lead applicant and the others as subcontractors. The subcontracts were projected to start April 2021, but due to partly Covid-related delays , the project started only in October 2022, and is currently projected to end 1 June 2023. Dr. Laitinen is the PI of the UCLan subcontract, and supervises the project subproject, which is being delivered by Dr. Bill Swalwell. |
| Collaborator Contribution | The partners provided modelling and observational data on coronal mass ejections observed by STEREO spacecraft. The UCLan group then utilised this data in analysing how inclusion of observations of the CME at Earth and L5 affect the forecasting of solar energetic particle fluxes at Earth. |
| Impact | Outputs are anticipated in terms of reports from first-second quarter of 2023. Publications are anticipated. |
| Start Year | 2019 |
| Description | Use of L5 Data in CME Propagation Models. P3-SWE-IV. |
| Organisation | University of Reading |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Proposal for an ESA-funded project for investigating use of a spacecraft at L5 to forecast space weather efffects due to coronal mass ejections. The project was approved, with RAL as lead applicant and the others as subcontractors. The subcontracts were projected to start April 2021, but due to partly Covid-related delays , the project started only in October 2022, and is currently projected to end 1 June 2023. Dr. Laitinen is the PI of the UCLan subcontract, and supervises the project subproject, which is being delivered by Dr. Bill Swalwell. |
| Collaborator Contribution | The partners provided modelling and observational data on coronal mass ejections observed by STEREO spacecraft. The UCLan group then utilised this data in analysing how inclusion of observations of the CME at Earth and L5 affect the forecasting of solar energetic particle fluxes at Earth. |
| Impact | Outputs are anticipated in terms of reports from first-second quarter of 2023. Publications are anticipated. |
| Start Year | 2019 |
| Description | Use of L5 Data in CME Propagation Models. P3-SWE-IV. |
| Organisation | University of St Andrews |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Proposal for an ESA-funded project for investigating use of a spacecraft at L5 to forecast space weather efffects due to coronal mass ejections. The project was approved, with RAL as lead applicant and the others as subcontractors. The subcontracts were projected to start April 2021, but due to partly Covid-related delays , the project started only in October 2022, and is currently projected to end 1 June 2023. Dr. Laitinen is the PI of the UCLan subcontract, and supervises the project subproject, which is being delivered by Dr. Bill Swalwell. |
| Collaborator Contribution | The partners provided modelling and observational data on coronal mass ejections observed by STEREO spacecraft. The UCLan group then utilised this data in analysing how inclusion of observations of the CME at Earth and L5 affect the forecasting of solar energetic particle fluxes at Earth. |
| Impact | Outputs are anticipated in terms of reports from first-second quarter of 2023. Publications are anticipated. |
| Start Year | 2019 |
| Description | School class visit, Cardinal Newman College, Preston, UK |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | Local |
| Primary Audience | Schools |
| Results and Impact | About 30 students attended a talk given by Dr Laitinen on Space Weather. Several students asked questions individually after the talk. |
| Year(s) Of Engagement Activity | 2024 |