UNDERSTANDING LAVA LAKES USING A NOVEL RADAR ALTIMETER
Lead Research Organisation:
University of Cambridge
Department Name: Geography
Abstract
We aim to investigate transient, oscillatory and secular behaviour related to the dynamics of magma degassing and transport, and reflected in the levels of lava lakes, and in the composition and fluxes of emitted gases and in other geophysical and geodetic parameters. We will achieve this through detailed studies of the lava lakes of two contrasting "laboratory volcanoes" (Kilauea and Erebus). While both volcanoes host lava lakes, their magma properties differ significantly in terms of composition, crystal content, viscosity and degassing styles. This will enable us to examine a variety of volcanic phenomena and to develop and evaluate hypotheses pertinent to understanding the behaviour of many open-vent volcanoes around the world.
Of particular importance to the project, we plan to acquire high-precision, high-temporal resolution and sustained measurements of lava lake level using an innovative and purpose-built radar instrument. This will be a novel adaptation of existing radar systems that have been used for other environmental applications, and builds from work on a prototype radar device that we are already designing and constructing ahead of our next field mission to Erebus volcano. The radar observations will be integrated, at the target volcanoes, with both operational and campaign measurements obtained from ultraviolet and infrared spectroscopy (for gas flux and composition), thermal imagers (for lake surface radiometry and velocimetry), gravimetry (for mass changes), continuous geodesy (to characterise ground deformation) and seismology. The new radar instrument will be integrated into the operational surveillance programme of the Hawaiian Volcano Observatory.
Our focus in the first half of the project will be on perfecting and installing the radar instrumentation. In the second half we will capitalise on the incoming datastreams, integrate them with our own and other ancillary observations of the target lava lakes, and use time-series analysis to identify temporal evolution of lava lake cycles and secular phenomena, and leads and lags between different parameters (e.g., lake level, gas flux, gas composition). This will help to tease out relationships and feedbacks between degassing, rheology, lake geometry and eruptive style (e.g., explosive vs. passive degassing at Erebus).
A key outcome of the project will be the development of hypotheses that explain the complex variations in lava lake level, gas flux and chemistry, mass change and surface deformation that we will have documented in the field. We expect the observed variability and contrasting dynamic regimes to represent both shallow (conduit and lava lake) and deeper (reservoir) processes.
A key to the ethos of the project is its combination of expertise in radar instrumentation (UCL) and volcanology (Cambridge), and the close collaboration of UK project members with partners in the USA (the US Geological Survey-Hawaiian Volcano Observatory, and the Mount Erebus Volcano Observatory, which operates from New Mexico Tech.). This is an ambitious project through which we hope to transform aspects of our understanding of magmatic processes, thanks to the planned synergy of electrical engineering, field science, and sophisticated data processing and time-series analysis. We aim to recruit a PhD student through the Cambridge-NERC Earth System Science DTP to develop theoretical aspects of lava lake fluid dynamics. The student would work closely with the PI and named researcher (Dr. Nial Peters).
Of particular importance to the project, we plan to acquire high-precision, high-temporal resolution and sustained measurements of lava lake level using an innovative and purpose-built radar instrument. This will be a novel adaptation of existing radar systems that have been used for other environmental applications, and builds from work on a prototype radar device that we are already designing and constructing ahead of our next field mission to Erebus volcano. The radar observations will be integrated, at the target volcanoes, with both operational and campaign measurements obtained from ultraviolet and infrared spectroscopy (for gas flux and composition), thermal imagers (for lake surface radiometry and velocimetry), gravimetry (for mass changes), continuous geodesy (to characterise ground deformation) and seismology. The new radar instrument will be integrated into the operational surveillance programme of the Hawaiian Volcano Observatory.
Our focus in the first half of the project will be on perfecting and installing the radar instrumentation. In the second half we will capitalise on the incoming datastreams, integrate them with our own and other ancillary observations of the target lava lakes, and use time-series analysis to identify temporal evolution of lava lake cycles and secular phenomena, and leads and lags between different parameters (e.g., lake level, gas flux, gas composition). This will help to tease out relationships and feedbacks between degassing, rheology, lake geometry and eruptive style (e.g., explosive vs. passive degassing at Erebus).
A key outcome of the project will be the development of hypotheses that explain the complex variations in lava lake level, gas flux and chemistry, mass change and surface deformation that we will have documented in the field. We expect the observed variability and contrasting dynamic regimes to represent both shallow (conduit and lava lake) and deeper (reservoir) processes.
A key to the ethos of the project is its combination of expertise in radar instrumentation (UCL) and volcanology (Cambridge), and the close collaboration of UK project members with partners in the USA (the US Geological Survey-Hawaiian Volcano Observatory, and the Mount Erebus Volcano Observatory, which operates from New Mexico Tech.). This is an ambitious project through which we hope to transform aspects of our understanding of magmatic processes, thanks to the planned synergy of electrical engineering, field science, and sophisticated data processing and time-series analysis. We aim to recruit a PhD student through the Cambridge-NERC Earth System Science DTP to develop theoretical aspects of lava lake fluid dynamics. The student would work closely with the PI and named researcher (Dr. Nial Peters).
Planned Impact
User engagement is an intrinsic part of our project because of the synergy of research and operational monitoring that will be achieved with the U.S. Geological Survey - Hawaiian Volcano Observatory (HVO).
We identify three groups of beneficiaries of our research:
(i) The USGS-HVO will benefit from the installation of a sophisticated and bespoke radar altimeter, which will enable operational surveillance of the lava lake level at Kilauea. This will contribute to assessment of volcanic activity, and thereby to HVO's role in risk reduction (up to 3 million people visit the Hawai'i Volcanoes National Park annually). The shift in activity to the summit crater of the volcano has resulted in closure of part of the National Park to the public but visitors can still be exposed to hazards associated with acid gas and aerosol emissions from the lava lake depending on prevailing winds. Because lava lake level is such a key descriptor of the state of the magmatic system, the installation of the proposed radar device will represent a significant advance in the operational work of HVO.
(ii) The wider (international) volcano observatory community, especially those concerned with monitoring basaltic volcanoes, stands to benefit from increased knowledge of magmatic processes, in addition to developments in interpretation of multi-parameter datasets. These advances will arise through the development and testing of hypotheses throughout the project, and the refinement of models to explain and interpret cycles and transitions that characterise many aspects of "open-vent" volcanic behaviour.
(iii) Industrial beneficiaries are expected from within the radar community, including civil and defence companies that UCL already collaborates with on other projects. The technology developed by the project will enable high precision range measurements using novel cross-correlation techniques and allow the acquisition of continuous time-series data sets. The project will greatly contribute to the skill set and experience of the named Researcher (Dr. Nial Peters), who will gain expertise in radar engineering, time-series analysis, fieldwork planning and making international collaborations work. This combination of skills in addition to the opportunities for professional networking across a range of research areas and institutions will build further his expertise and recognition ahead of the next stage of his research career.
We identify three groups of beneficiaries of our research:
(i) The USGS-HVO will benefit from the installation of a sophisticated and bespoke radar altimeter, which will enable operational surveillance of the lava lake level at Kilauea. This will contribute to assessment of volcanic activity, and thereby to HVO's role in risk reduction (up to 3 million people visit the Hawai'i Volcanoes National Park annually). The shift in activity to the summit crater of the volcano has resulted in closure of part of the National Park to the public but visitors can still be exposed to hazards associated with acid gas and aerosol emissions from the lava lake depending on prevailing winds. Because lava lake level is such a key descriptor of the state of the magmatic system, the installation of the proposed radar device will represent a significant advance in the operational work of HVO.
(ii) The wider (international) volcano observatory community, especially those concerned with monitoring basaltic volcanoes, stands to benefit from increased knowledge of magmatic processes, in addition to developments in interpretation of multi-parameter datasets. These advances will arise through the development and testing of hypotheses throughout the project, and the refinement of models to explain and interpret cycles and transitions that characterise many aspects of "open-vent" volcanic behaviour.
(iii) Industrial beneficiaries are expected from within the radar community, including civil and defence companies that UCL already collaborates with on other projects. The technology developed by the project will enable high precision range measurements using novel cross-correlation techniques and allow the acquisition of continuous time-series data sets. The project will greatly contribute to the skill set and experience of the named Researcher (Dr. Nial Peters), who will gain expertise in radar engineering, time-series analysis, fieldwork planning and making international collaborations work. This combination of skills in addition to the opportunities for professional networking across a range of research areas and institutions will build further his expertise and recognition ahead of the next stage of his research career.
Publications
Ilyinskaya E
(2021)
Rapid metal pollutant deposition from the volcanic plume of Kilauea, Hawai'i
in Communications Earth & Environment
Ilyinskaya E
(2021)
Rapid metal pollutant deposition from the volcanic plume of Kilauea, Hawai'i
Köhler A
(2020)
mGEODAR-A Mobile Radar System for Detection and Monitoring of Gravitational Mass-Movements.
in Sensors (Basel, Switzerland)
Le Losq C
(2020)
In situ XANES study of the influence of varying temperature and oxygen fugacity on iron oxidation state and coordination in a phonolitic melt
in Contributions to Mineralogy and Petrology
Mason E
(2021)
Volatile metal emissions from volcanic degassing and lava-seawater interactions at Kilauea Volcano, Hawai'i
in Communications Earth & Environment
Description | Successful deployment of prototype radar devices for monitoring lava lake height at Mount Erebus and Kilauea volcanoes. Progress made with data analysis. Key paper published reporting operational principles, data analysis approaches, and examples of lava lake height variation observed at Mount Erebus. |
Exploitation Route | The radar device is already being used for other applications, and Dr. Nial Peters obtained another position at UCL on the back of his experience with this project. |
Sectors | Aerospace Defence and Marine Electronics Environment |
Description | Research instrument featured in BBC broadcast |
First Year Of Impact | 2018 |
Sector | Electronics,Environment |
Impact Types | Cultural |
Title | Radar system |
Description | A frequency modulated continuous wave (FMCW) radar operating at X-band (10.2-10.6 GHz). |
Type Of Material | Improvements to research infrastructure |
Year Produced | 2018 |
Provided To Others? | Yes |
Impact | Our radar system is being used to study human micro-doppler signatures, and for measurements of drone propellers as part of the "Multistatic C-UAV Target Classification" project at UCL. |
Title | Filter pack and cascade impactor samples of gas and aerosol particulate matter on the Island of Hawai'i (2018, 2019) |
Description | This dataset reports chemical speciation of airborne gas and aerosol particulate matter (PM) sampled in various locations on the Island of Hawai'i in 2018 and 2019. The 2018 samples were collected during a large eruption of Kilauea volcano. The 2019 samples were collected during a period of very low volcanic activity. Samples were collected in several locations on the Island of Hawai'i, Hawaii, USA. Time-series samples were collected at -Leilani Estates -Volcano village -Pahala, Ocean View -Kailua-Kona -Mauna Loa Observatory in 2018 and 2019. Point-source samples were collected at the following locations -The main erupting vent 'Fissure 8' on the Kilauea Volcano in 2018, and repeated in its vicinity post-eruption in 2019 - The lava ocean entry point in 2018 and repeated in its vicinity post-eruption in 2019. The samples were collected using filter packs (FP) and Sioutas cascade impactors (SKC). The instruments were used at ground-level in all cases except for samples FP_08_1, FP_ 09_1, FP_09_2, SKC_08 and SKC_09 which were attached to an Unoccupied Aircraft System (UAS) in order to safely access the erupting vent and the lava ocean entry. The samples were then analysed using inductively-coupled plasma mass spectroscopy (ICP-MS), inductively-coupled plasma optical emission spectroscopy (ICP-OES) and ion chromatography (IC). Sample analysis was done at the University of Leeds, United Kingdom (2018 samples) and the University of Leeds and Open University, United Kingdom (2019 samples). The results are reported as concentration per volume of air sampled (µg/m^3) to 2 significant figures. This was done to - assess the dispersion of major and trace elements in a volcanic plume, and quantify their depletion rates from the source into the far-field (up to ~240 km downwind) - assess the impact of volcanic emissions on the composition of the local atmosphere. The data were produced as a result of a collaborative project between the Universities of Leeds, Cambridge, Oxford (UK), Hawaiian Volcano Observatory of the United States Geological Survey, and the University of Hawai'i at Manoa (USA). |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
URL | https://catalogue.ceda.ac.uk/uuid/656204c257144708a641507c78187aaa |
Description | USGS-HVO |
Organisation | US Geological Survey |
Department | USGS Hawaiian Volcano Observatory |
Country | United States |
Sector | Public |
PI Contribution | Planning fieldwork for summer 2017 - more to report next year |
Collaborator Contribution | Planning fieldwork for summer 2017 - more to report next year |
Impact | Planning fieldwork for summer 2017 - more to report next year |
Start Year | 2016 |
Title | EredarII |
Description | Low-power, X-band FMCW radar system. Although primarily designed for lava lake monitoring, the highly-configurable design of the hardware has meant that the system has also been used for avalanche monitoring. |
Type Of Technology | Detection Devices |
Year Produced | 2017 |
Impact | The radar has allowed us to make the first long-duration study of the level of Erebus volcano's active lava lake. Initial analysis of these data suggest that previous theories about the mechanisms driving the lake are incorrect. |
Description | HVO Volcano Watch article |
Form Of Engagement Activity | A magazine, newsletter or online publication |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Public/other audiences |
Results and Impact | Contribution of an article to the Hawaiian Volcano Observatory's online weekly newsletter "Volcano Watch" detailing the fieldwork conducted in January 2018 using the new radar system developed during this project. |
Year(s) Of Engagement Activity | 2018 |
URL | https://volcanoes.usgs.gov/observatories/hvo/hvo_volcano_watch.html |
Description | Hertforshire Geological Society talk |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | Regional |
Primary Audience | Public/other audiences |
Results and Impact | Lecture and general discussion / questions session at meeting of local Geology interest group. Talk was well received and a request was made for participation in future outreach events run by the group. |
Year(s) Of Engagement Activity | 2017 |
URL | http://www.hertsgeolsoc.ology.org.uk/index.htm |
Description | Home Counties Regional Group Meeting |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | Regional |
Primary Audience | Public/other audiences |
Results and Impact | Talk with discussion/questions session afterwards at Home Counties Regional Group (Geology interest group) meeting. Discussion session was lively with several audience members requesting further information. A follow-up article is due to appear in the group's newsletter. |
Year(s) Of Engagement Activity | 2018 |