Understanding the Energy Pathways of Earth's Magnetosphere
Lead Research Organisation:
Lancaster University
Department Name: Physics
Abstract
Electronic devices are part of our everyday lives. They allow us to message each other, provide energy for our homes, and control critical systems like air traffic, but they are vulnerable. Space Weather describes how electric and magnetic fields change around Earth. Just like normal weather there are storms in space and when a Space Weather "geomagnetic storm" happens, our electronic devices can be damaged so it is extremely important that we can predict when these storms will happen. I aim to gain new insights into the physics behind Space Weather events.
The magnetosphere is the magnetic environment that surrounds Earth like a bubble. It is filled with plasma, an electrically conducting mix of particles, which creates electric and magnetic fields as it moves. Understanding how plasma moves is crucial for understanding Space Weather. Particles from the Sun, can put energy into the magnetosphere where it is stored until it can be released. When the energy is released, or unloaded, some of it can end up in the atmosphere through the aurora and some of it can be put into the plasma in the magnetosphere. When the plasma's energy levels are particularly high, a geomagnetic storm happens. How the energy unloading happens in a storm is poorly understood. This is because it happens with a delay from the dayside loading, which makes them tricky to model. My research uses a combination of data from spacecraft and ground-based observatories to understand the amount of energy that is put into the magnetosphere and how this changes over time. With the knowledge of the time-history, and measurements of the unloading, we will then be able to model the magnetosphere's response to the driving using novel methods.
My research aims to understand the timescales of these responses, which will allow us to understand the physics behind Space Weather. This will lead to long-term benefits for society by strengthening the foundations for predicting geomagnetic storms.
The magnetosphere is the magnetic environment that surrounds Earth like a bubble. It is filled with plasma, an electrically conducting mix of particles, which creates electric and magnetic fields as it moves. Understanding how plasma moves is crucial for understanding Space Weather. Particles from the Sun, can put energy into the magnetosphere where it is stored until it can be released. When the energy is released, or unloaded, some of it can end up in the atmosphere through the aurora and some of it can be put into the plasma in the magnetosphere. When the plasma's energy levels are particularly high, a geomagnetic storm happens. How the energy unloading happens in a storm is poorly understood. This is because it happens with a delay from the dayside loading, which makes them tricky to model. My research uses a combination of data from spacecraft and ground-based observatories to understand the amount of energy that is put into the magnetosphere and how this changes over time. With the knowledge of the time-history, and measurements of the unloading, we will then be able to model the magnetosphere's response to the driving using novel methods.
My research aims to understand the timescales of these responses, which will allow us to understand the physics behind Space Weather. This will lead to long-term benefits for society by strengthening the foundations for predicting geomagnetic storms.
People |
ORCID iD |
| Maria-Theresia Walach (Principal Investigator / Fellow) |
Publications
Waters J
(2025)
Auroral Acceleration at the Northern Magnetic Pole During Sub-Alfvénic Solar Wind Flow at Earth
in Journal of Geophysical Research: Space Physics
Archer M
(2024)
Crucial future observations and directions for unveiling magnetopause dynamics and their geospace impacts
in Frontiers in Astronomy and Space Sciences
Killey S
(2025)
Identifying Typical Relativistic Electron Pitch Angle Distributions: Evolution During Geomagnetic Storms
in Geophysical Research Letters
Day E
(2024)
Observation of Quiet-Time Mid-Latitude Joule Heating and Comparisons With the TIEGCM Simulation
in Journal of Geophysical Research: Space Physics
Walach M
(2025)
Reliability of Matching AMPERE Field-Aligned Current Boundaries With SuperDARN Lower Latitude Ionospheric Convection Boundaries During Geomagnetic Storms
in Journal of Geophysical Research: Space Physics
Walach M
(2024)
SMILE Winter Campaign
in RAS Techniques and Instruments
Smith A
(2024)
Space Weather Forecasts of Ground Level Space Weather in the UK: Evaluating Performance and Limitations
in Space Weather
| Title | Combined SuperDARN and AMPERE plots |
| Description | Combined SuperDARN and AMPERE plots for the events described by Walach et al. (submitted to JGR: Space Physics), "Reliability of Matching AMPERE Field-Aligned Current Boundaries with SuperDARN Lower Latitude Ionospheric Convection Boundaries During Geomagnetic Storms": 18:00 UT on 19 January 2016 to 18:00 UT on 21 January 2016; 20:20 UT on 19 December 2015 to 20:20 UT on 21 December 2015; 20:10 UT on 14 July 2012 to 20:10 UT on 16 July 2012. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2024 |
| Provided To Others? | Yes |
| Impact | 24 views, 251 downloads so far. |
| URL | https://zenodo.org/records/13493214 |
| Title | Geomagnetic Storm List 1981-2022 |
| Description | This is the geomagnetic storm list generated using the same method as for the paper 'SuperDARN observations during geomagnetic storms, geomagnetically active times and enhanced solar wind driving', by M.-T. Walach & A. Grocott, published in JGR, 2019, doi:10.1029/2019JA026816. The list was generated using an algorithm and is based on Sym-H. The event list is an extension of https://doi.org/10.17635/lancaster/researchdata/622Description |
| Type Of Material | Database/Collection of data |
| Year Produced | 2024 |
| Provided To Others? | Yes |
| Impact | this dataset has led to three further research collaborations. |
| URL | https://www.research.lancs.ac.uk/portal/en/datasets/geomagnetic-storm-list-19812022(a5545ef6-4bf6-40... |
| Title | Lower latitude boundaries from AMPERE and SuperDARN |
| Description | Combined SuperDARN and AMPERE boundaries (\Lambda_{Walach} and \Lambda_{Fogg}), respectively for the events described by Walach et al. (submitted to JGR: Space Physics), "Reliability of Matching AMPERE Field-Aligned Current Boundaries with SuperDARN Lower Latitude Ionospheric Convection Boundaries During Geomagnetic Storms": 18:00UT on 19 January 2016 to 18:00 UT on 21 January 2016; 20:20 UTon 19 December 2015 to 20:20 UT on 21 December 2015; 20:10 UTon 14 July 2012 to 20:10 UT on 16 July 2012. The SuperDARN boundaries (file format: *_maria_hmb.txt) are in the format: year, month, day, hour, minute, second, HMB at midnight [geomagnetic latitude], n (the number of SuperDARN vectors in the map) and SYM-H. The AMPERE boundaries (file format: *.amphmb) are in the format: year, month, day, hour, minute, second, HMB at midnight [geomagnetic latitude]. All files are in ASCII format. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2024 |
| Provided To Others? | Yes |
| Impact | 17 views and 35 downloads so far. |
| URL | https://zenodo.org/doi/10.5281/zenodo.13495836 |
| Description | International Space Science Institute International Team 546 Membership |
| Organisation | International Space Science Institute (ISSI) |
| Country | Switzerland |
| Sector | Academic/University |
| PI Contribution | International Space Science Institute International Team on Magnetohydrodynamic Surface Waves at Earth's Magnetosphere (and Beyond). 2 international team meetings were participated in and common research directions were explored. The research led to several research publications, two of which were co-authored by Dr Walach. |
| Collaborator Contribution | Dr Walach provided expertise in data analysis and intellectual contributions to the research directions and publications. |
| Impact | Walach et al. (2024) SMILE Winter Campaign. RAS Techniques and Instruments, 3, 556-564. https://doi.org/10.1093/rasti/rzae038 Archer et al. (2024) Crucial Future Observations and Directions for Unveiling Magnetopause Dynamics and their Geospace Impacts. Frontiers in Astronomy and Space Sciences, 11. |
| Start Year | 2023 |
| Description | Public engagement event: Campus in the city (Lancaster) |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | Regional |
| Primary Audience | Public/other audiences |
| Results and Impact | General outreach and engagement event held by the University all over Lancaster city centre (and beyond). We hosted an engagement activity centred around research questions about the solar system, which attracted 180-200 people of all ages. Pieces of paper with question topics engaged the public also and the answers informed LU researchers on the level of engagement and interest, as well as areas of particular interest. 7% of people (4) taking part in the survey (23) said they had learnt "A stellar amount!" about the solar system; 60% of people taking part said they had learnt "Lots!" and 21% said they had learnt more than "Quite a bit" but ranked it less than "Lots!". No-one taking part in the survey ranked their knowledge increase of less than "Quite a bit". Other options were "Not a lot" and "Nothing". |
| Year(s) Of Engagement Activity | 2024 |