A Consolidated Grant Proposal for Solar and Planetary Science at the University of Leicester, 2022 - 2025
Lead Research Organisation:
University of Leicester
Department Name: Physics and Astronomy
Abstract
We propose a world-class programme of research that focuses on 3 main areas of study concerned with our solar system. The first involves study of the outer environments of the planets where the gas is ionised, such that it not only feels the gravitational pull of the planet, but also interacts strongly with its magnetic and electric fields. In the second area we seek to study the origin and evolution of solar system bodies, through examination of materials from asteroid, chondrite and lunar samples, and through laboratory-based exploration of X-ray fluorescence from Mercury analogues. The third area will employ spectroscopy from the James Webb Space Telescope (JWST) and ground observatories to explore the planetary stratospheres and tropospheres at the ice giants Uranus and Neptune.
Previous work in the first area shows that the outer environments of the planets vary widely, determined by the interaction with the plasma that blows continuously from the Sun on the outside, and the interaction with the planet and its moons on the inside. The solar wind is prone to outbursts that can lead to magnetic storms and bright auroras at Earth, as well as varying strongly over the solar cycle, and with distance from the Sun. Its interaction with the planets then depends on whether the planet is magnetised, has an atmosphere, and has active moons. We will use MESSENGER data to study Mercury close to the Sun, a planet that has a magnetic field but almost no atmosphere; use the constellation of spacecraft at Mars, more distant from the Sun, which has an atmosphere but no strong magnetic field to prevent its erosion by the solar wind; and combine multi-spacecraft and ground instrumentation at Earth, at intermediate distances having both an atmosphere and a magnetic field. We will also study the strongly magnetized giant planets Jupiter and Saturn using data from the Juno mission at Jupiter and Cassini at Saturn, combined with observations of the auroras at ultraviolet wavelengths using the Hubble Space Telescope and at infrared wavelengths using large ground-based telescopes. Auroras are caused by large-scale electric currents flowing between the outer environments and the upper ionized atmospheres, which communicate force between these regions. Overall emphasis will be on the complex physical processes that couple the solar wind on the outside, the magnetic field surrounding the planet (if any), and the planetary atmospheres or surface on the inside.
In the second area, laboratory studies, we will analyse material returned from C-class asteroid Ryugu by the Hayabusa2 mission. We will make complementary analyses on Apollo lunar regolith grains and recent, unique carbonaceous chondrite falls to build a new understanding of space weathering and C-class asteroid parent body processes. This project builds on the leading expertise we have in the microanalysis of planetary materials, through electron microscopy at ePSIC and UoL, and synchrotron-based X-ray spectroscopy. Laboratory work focused on Mercury will centre on the MIXS Ground Reference Facility, a purpose-built system to allow detailed analysis of X-ray fluorescence, induced using an X-ray or electron source, for bespoke surface analogues. This laboratory facility will uniquely allow us to expand our science programme using the MIXS data from the BepiColombo mission, both in relation to the dayside surface composition goals at global and local scales on Mercury, and in terms of the nightside magnetosphere-surface interaction which produces a significant X-ray fluorescence associated with electron bombardment.
The final theme leverages Leicester's leadership of the guaranteed-time giant planets programme on the JWST, exploiting MIRI spectroscopic maps of the Ice Giants Uranus and Neptune, combined with a ground-based observation programme, to understand how stratospheric circulation, photochemistry, and tropospheric meteorology shape the atmospheres of sub-giant-sized worlds.
Previous work in the first area shows that the outer environments of the planets vary widely, determined by the interaction with the plasma that blows continuously from the Sun on the outside, and the interaction with the planet and its moons on the inside. The solar wind is prone to outbursts that can lead to magnetic storms and bright auroras at Earth, as well as varying strongly over the solar cycle, and with distance from the Sun. Its interaction with the planets then depends on whether the planet is magnetised, has an atmosphere, and has active moons. We will use MESSENGER data to study Mercury close to the Sun, a planet that has a magnetic field but almost no atmosphere; use the constellation of spacecraft at Mars, more distant from the Sun, which has an atmosphere but no strong magnetic field to prevent its erosion by the solar wind; and combine multi-spacecraft and ground instrumentation at Earth, at intermediate distances having both an atmosphere and a magnetic field. We will also study the strongly magnetized giant planets Jupiter and Saturn using data from the Juno mission at Jupiter and Cassini at Saturn, combined with observations of the auroras at ultraviolet wavelengths using the Hubble Space Telescope and at infrared wavelengths using large ground-based telescopes. Auroras are caused by large-scale electric currents flowing between the outer environments and the upper ionized atmospheres, which communicate force between these regions. Overall emphasis will be on the complex physical processes that couple the solar wind on the outside, the magnetic field surrounding the planet (if any), and the planetary atmospheres or surface on the inside.
In the second area, laboratory studies, we will analyse material returned from C-class asteroid Ryugu by the Hayabusa2 mission. We will make complementary analyses on Apollo lunar regolith grains and recent, unique carbonaceous chondrite falls to build a new understanding of space weathering and C-class asteroid parent body processes. This project builds on the leading expertise we have in the microanalysis of planetary materials, through electron microscopy at ePSIC and UoL, and synchrotron-based X-ray spectroscopy. Laboratory work focused on Mercury will centre on the MIXS Ground Reference Facility, a purpose-built system to allow detailed analysis of X-ray fluorescence, induced using an X-ray or electron source, for bespoke surface analogues. This laboratory facility will uniquely allow us to expand our science programme using the MIXS data from the BepiColombo mission, both in relation to the dayside surface composition goals at global and local scales on Mercury, and in terms of the nightside magnetosphere-surface interaction which produces a significant X-ray fluorescence associated with electron bombardment.
The final theme leverages Leicester's leadership of the guaranteed-time giant planets programme on the JWST, exploiting MIRI spectroscopic maps of the Ice Giants Uranus and Neptune, combined with a ground-based observation programme, to understand how stratospheric circulation, photochemistry, and tropospheric meteorology shape the atmospheres of sub-giant-sized worlds.
Publications
Malsky I
(2024)
A Direct Comparison between the Use of Double Gray and Multiwavelength Radiative Transfer in a General Circulation Model with and without Radiatively Active Clouds
in The Astrophysical Journal
Sinclair J
(2023)
A High Spatial and Spectral Resolution Study of Jupiter's Mid-infrared Auroral Emissions and Their Response to a Solar Wind Compression
in The Planetary Science Journal
Murphy M
(2023)
A Lack of Variability between Repeated Spitzer Phase Curves of WASP-43b
in The Astronomical Journal
Kempton E
(2023)
A reflective, metal-rich atmosphere for GJ 1214b from its JWST phase curve
in Nature
Stergiopoulou K
(2022)
A Two-Spacecraft Study of Mars' Induced Magnetosphere's Response to Upstream Conditions
in Journal of Geophysical Research: Space Physics
De Pater I
(2023)
An Energetic Eruption With Associated SO 1.707 Micron Emissions at Io's Kanehekili Fluctus and a Brightening Event at Loki Patera Observed by JWST
in Journal of Geophysical Research: Planets
Hueso R
(2023)
An intense narrow equatorial jet in Jupiter's lower stratosphere observed by JWST
in Nature Astronomy
Krishnan A
(2023)
Analysis of Two Selected Solar Events in 2011 and 2015 With Mars Express Radio Occultation Data
in Radio Science
Kamran A
(2022)
Auroral Field-Aligned Current Signatures in Jupiter's Magnetosphere: Juno Magnetic Field Observations and Physical Modeling
in Journal of Geophysical Research: Space Physics
Persson M
(2022)
BepiColombo mission confirms stagnation region of Venus and reveals its large extent.
in Nature communications
Palmerio E
(2022)
CMEs and SEPs During November-December 2020: A Challenge for Real-Time Space Weather Forecasting
in Space Weather
Bockelée-Morvan D
(2024)
Composition and thermal properties of Ganymede's surface from JWST/NIRSpec and MIRI observations
in Astronomy & Astrophysics
King O
(2022)
Compositional Mapping of Europa Using MCMC Modeling of Near-IR VLT/SPHERE and Galileo/NIMS Observations
in The Planetary Science Journal
King O
(2023)
Custom JWST NIRSpec/IFU and MIRI/MRS Data Reduction Pipelines for Solar System Targets
in Research Notes of the AAS
Wang Y
(2022)
Dependencies of GPS Scintillation Indices on the Ionospheric Plasma Drift and Rate of Change of TEC Around the Dawn Sector of the Polar Ionosphere
in Journal of Geophysical Research: Space Physics
Bradley T
(2022)
Detection of Equatorial Plasma Velocity Modulations Associated With Planetary Period Oscillations in Saturn's Magnetosphere
in Journal of Geophysical Research: Space Physics
Feinstein AD
(2023)
Early Release Science of the exoplanet WASP-39b with JWST NIRISS.
in Nature
Alberti T
(2022)
Editorial: Interplanetary medium variability as observed in the new era of spacecraft missions
in Frontiers in Astronomy and Space Sciences
Cecconi B
(2022)
Effect of an Interplanetary Coronal Mass Ejection on Saturn's Radio Emission
in Frontiers in Astronomy and Space Sciences
Fogg A
(2023)
Extreme Value Analysis of Ground Magnetometer Observations at Valentia Observatory, Ireland
in Space Weather
Krcelic P
(2023)
Fine-Scale Electric Fields and Joule Heating From Observations of the Aurora
in Journal of Geophysical Research: Space Physics
Bower G
(2023)
Formation and Motion of Horse Collar Aurora Events
in Journal of Geophysical Research: Space Physics
Bower G
(2022)
Formation and motion of horse collar aurora events