From The Rosenstiel School of Marine and Atmospheric Science At The University of Miami: “Researchers’ study accurately predicted location of Mauna Loa eruption”
From The Rosenstiel School of Marine and Atmospheric Science
At
12.2.22
Robert C. Jones Jr.
Mauna Loa on the Big Island. https://www.freeworldmaps.net
Aerial image of fissure 3 on Mauna Loa’s Northeast Rift Zone erupting the morning of Nov. 30, 2022. Fissure 3 remains the dominant source of the largest lava flow being generated during the eruption. Photo: K. Mulliken/U.S. Geological Survey.
A year before the largest active volcano in the world erupted, research by two University of Miami scientists revealed which of the two rift zones of the Mauna Loa volcano would spew magma.
Research conducted by a University of Miami scientist and his graduate assistant accurately predicted which of the two rift zones of Hawaii’s Mauna Loa volcano would erupt.
The Mauna Loa, the world’s largest active volcano, began erupting on Nov. 27 for the first time in nearly 40 years, spewing lava 100 feet to 200 feet into the air.
Using a satellite-based technique called interferometric synthetic aperture radar (InSAR) to measure surface displacements and to estimate how much magma was accumulating under the volcano during a six-year period (2014-2020), the two researchers proposed last year that the next movement of magma would be upwards into the volcano’s summit and then northward, opening fissures in Mauna Loa’s northeast rift zone.
“And that’s exactly what happened. We predicted it,” said Falk Amelung, a professor of marine geosciences at the University’s Rosenstiel School of Marine, Atmospheric, and Earth Science, who once lived on Oahu, part of the Hawaiian island chain, and has studied Mauna Loa extensively. “This represents years of hard work and intensive research paying off and shows that the precise evaluation of stress changes can be a powerful tool for informed forecasts of future activity.”
Amelung and research assistant Bhuvan Varugu published their research in Scientific Reports [below], a peer-reviewed open-access journal published by Nature Portfolio. The study was funded by NASA’s Earth Science Division.
Figure 1
(a) InSAR LOS Velocity from January 2014 to May 2020 over Mauna Loa from ascending Cosmo-SkyMed imagery together with seismicity. (b) Cumulative GPS horizontal velocities for the 2010–2014 and the three 2014–2020 time periods. (c) InSAR LOS and GPS horizontal displacement time series. (d–f) monthly number of earthquakes (> M 1.0) for three sections of Mauna Loa: (d) under the summit (0–6 km depth), (e) near the eastern basal decollement (7–15 km depth), (f) near the western decollement fault (7–15 km depth). East–west horizontal and vertical velocities from ascending and descending InSAR during (g,h) 2002–2005, (i,j) 2014–2015, (k,l) 2015–2018, and (m,n) 2018–2020. Color scale is adjusted to enhance the shift in locus of deformation. In (a): white and purple rectangles: sections for seismicity counts; black dots: seismicity; purple star: reference point; blue triangle: location of InSAR timeseries in (c); vertical lines in (c–e): time periods discussed in paper; horizontal lines in (g–n): to highlight the southward shift of deformation during 2015–2018.
Figure 2
InSAR and GPS data together with modelling results for the three time periods. (a–f) Ascending and descending InSAR velocities, (g–l) best-fitting model predictions, (m–r) data and model predictions in a profile perpendicular to the rift zone, (s–u) GPS data (red) and model predictions (blue). (v) GPS data and model prediction for the 2010–2014 period. 
Potency rates of the dike-like magma body. Bottom values in (w): total potency for the time period. White line: opening dislocation; White circle: mogi source; black rectangles: dislocation along decollement; blue dotted line: profile location for m-r; purple corners: Area shown in (a–l).
When Amelung learned of the eruption, “I was terribly worried that the dike would spread southward because of the lava flow hazards. But once it became clear that the dike had propagated to the north, I was relieved to know that no one would be in harm’s way and that the many years of our hard work and research had produced accurate results.”
Late last week, lava flows from the Mauna Loa eruption were moving toward a main highway. And an update issued on Dec. 1 by the U.S. Geological Survey confirmed that the lava flows “are traveling to the north toward the Daniel K. Inouye Highway (Saddle Road) but have reached relatively flatter ground and have slowed down significantly as expected.”
At the time Amelung and Varugu initiated their Mauna Loa study nearly seven years ago, data from synthetic aperture radar (SAR) satellites was not easy to acquire, making it a challenge for the scientists to get a complete picture of the volcano’s ground movements, according to Amelung.
To clear that hurdle, Amelung helped create the Geohazard Supersites and Natural Laboratory, an international partnership of NASA and five other space agencies that pool their satellite resources to make SAR data of geohazard sites more readily available to the scientific community. For their Mauna Loa study, the two researchers used data supplied by the Italian Space Agency. “Now, we can do complex geohazard assessments of volcanic sites within a few hours,” Amelung said. “It’s a splendid example of scientific progress.”
When Amelung lived on Oahu, he would visit the big island of Hawaii every few months to study Mauna Loa, hiking up to its summit several times.
“It is fascinating because it is so big,” he said. “It’s a natural laboratory to understand earthquake-volcano interactions. But it’s important to remember that it is hazardous. This time, we seem to have been lucky as far as the eruption not causing much damage. An eruption in the south would have reached populated areas within hours.”
Amelung and Varugu responded to questions to explain their research and the nature of volcanic eruptions in greater detail.
Detail the exact nature of your Mauna Loa study and how it predicted the location of this latest eruption.
Varugu: As magma recharges under a volcano, it often exhibits ground deformation at the surface. We derived the ground deformation on Mauna Loa volcano from satellite images over six years (2014-2020) and mathematically inverted it to infer the magma body’s location, shape, and growth. We studied the factors affecting the magma growth as it reaches the shallow level under the volcano and as stress accumulated due to magma pressurization. In 2015 the area of magma accumulation moved southward but there was no eruption, and then it returned to the original location. Overall, from six years of magma pressurization, we identified significant stress accumulation in the upward and northward of the shallow magma body and determined them as future directions of magma growth. The magma recharge continued ever since (2014 to 2022), and the current eruption occurred as the magma first moved upward into the summit and then north, opening fissures into the northeast rift zone of the volcano. So, our study helped identify zones of stress accumulation that can be potential future eruption zones.
What early signs, such as increased earthquake activity, indicated that the Mauna Loa was going to erupt?
Amelung: In August and September, the number of shallow earthquakes as well as the rate of inflation increased by a factor of about three.
Could we potentially see a large earthquake result from this eruption?
Amelung: Yes. Hawaiian volcanoes have horizontal décollement faults under the flanks which occasionally rupture in large earthquakes. This eruption started with the intrusion of a blade-like magma body into the volcanic edifice known as a dike. This dike loaded the fault under the eastern flank. However, inflation in the prior 20 years primarily loaded the fault under the western flank. Unfortunately, we don’t know at what threshold stress the fault will rupture. A significant earthquake, magnitude 6 or greater, can occur at any time. But it may also require additional loading after the eruption by new magma intrusion.
What’s unique about the Mauna Loa?
Varugu: Mauna Loa is the largest subaerial volcano on Earth and has had a rich eruption history, approximately 33 times in the past 200 years. Its mammoth size is an indication of historic lava flows. And it is fascinating that many eruptions at Mauna Loa have been preceded or succeeded by an earthquake. So, a strong correlation exists between earthquakes and eruptions there.
How are volcanic eruptions and earthquakes linked? Can earthquakes trigger volcanic eruptions and can volcanic eruptions trigger earthquakes?
Amelung: Every eruption is associated with volcano-tectonic seismicity, but these small earthquakes represent the breakage of the rock in response to ascending magma. They are different from tectonic earthquakes that occur on tectonic faults. If there is a tectonic fault near an active volcano, it might be triggered. There are two possible triggering mechanisms. The first is the removal of magma from the magma reservoir that unclamps the fault. The second is magma intrusions into the volcanic edifice that can load the fault. This second mechanism is at work at Mauna Loa.
Science paper:
Scientific Reports
See the science paper for instructive material with more images.
See the full article here.
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The Rosenstiel School of Marine and Atmospheric Science is an academic and research institution for the study of oceanography and the atmospheric sciences within the University of Miami. It is located on a 16-acre (65,000 m^²) campus on Virginia Key in Miami, Florida. It is the only subtropical applied and basic marine and atmospheric research institute in the continental United States.
Up until 2008, RSMAS was solely a graduate school within the University of Miami, while it jointly administrated an undergraduate program with UM’s College of Arts and Sciences. In 2008, the Rosenstiel School has taken over administrative responsibilities for the undergraduate program, granting Bachelor of Science in Marine and Atmospheric Science (BSMAS) and Bachelor of Arts in Marine Affairs (BAMA) baccalaureate degree. Master’s, including a Master of Professional Science degree, and doctorates are also awarded to RSMAS students by the UM Graduate School.
The Rosenstiel School’s research includes the study of marine life, particularly Aplysia and coral; climate change; air-sea interactions; coastal ecology; and admiralty law. The school operates a marine research laboratory ship, and has a research site at an inland sinkhole. Research also includes the use of data from weather satellites and the school operates its own satellite downlink facility. The school is home to the world’s largest hurricane simulation tank.
The University of Miami is a private research university in Coral Gables, Florida. As of 2020, the university enrolled approximately 18,000 students in 12 separate colleges and schools, including the Leonard M. Miller School of Medicine in Miami’s Health District, a law school on the main campus, and the Rosenstiel School of Marine and Atmospheric Science focused on the study of oceanography and atmospheric sciences on Virginia Key, with research facilities at the Richmond Facility in southern Miami-Dade County.
The university offers 132 undergraduate, 148 master’s, and 67 doctoral degree programs, of which 63 are research/scholarship and 4 are professional areas of study. Over the years, the university’s students have represented all 50 states and close to 150 foreign countries. With more than 16,000 full- and part-time faculty and staff, The University of Miami is a top 10 employer in Miami-Dade County. The University of Miami’s main campus in Coral Gables has 239 acres and over 5.7 million square feet of buildings.
The University of Miami is classified among “R1: Doctoral Universities – Very high research activity”. The University of Miami research expenditure in FY 2019 was $358.9 million. The University of Miami offers a large library system with over 3.9 million volumes and exceptional holdings in Cuban heritage and music.
The University of Miami also offers a wide range of student activities, including fraternities and sororities, and hundreds of student organizations. The Miami Hurricane, the student newspaper, and WVUM, the student-run radio station, have won multiple collegiate awards. The University of Miami’s intercollegiate athletic teams, collectively known as the Miami Hurricanes, compete in Division I of the National Collegiate Athletic Association. The University of Miami’s football team has won five national championships since 1983 and its baseball team has won four national championships since 1982.
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The University of Miami is classified among “R1: Doctoral Universities – Very high research activity”. In fiscal year 2016, The University of Miami received $195 million in federal research funding, including $131.3 million from the Department of Health and Human Services and $14.1 million from the National Science Foundation. Of the $8.2 billion appropriated by Congress in 2009 as a part of the stimulus bill for research priorities of The National Institutes of Health, the Miller School received $40.5 million. In addition to research conducted in the individual academic schools and departments, Miami has the following university-wide research centers:
The Center for Computational Science
The Institute for Cuban and Cuban-American Studies (ICCAS)
Leonard and Jayne Abess Center for Ecosystem Science and Policy
The Miami European Union Center: This group is a consortium with Florida International University (FIU) established in fall 2001 with a grant from the European Commission through its delegation in Washington, D.C., intended to research economic, social, and political issues of interest to the European Union.
The Sue and Leonard Miller Center for Contemporary Judaic Studies
John P. Hussman Institute for Human Genomics – studies possible causes of Parkinson’s disease, Alzheimer’s disease and macular degeneration.
Center on Research and Education for Aging and Technology Enhancement (CREATE)
Wallace H. Coulter Center for Translational Research
The Miller School of Medicine receives more than $200 million per year in external grants and contracts to fund 1,500 ongoing projects. The medical campus includes more than 500,000 sq ft (46,000 m^2) of research space and the The University of Miami Life Science Park, which has an additional 2,000,000 sq ft (190,000 m^2) of space adjacent to the medical campus. The University of Miami’s Interdisciplinary Stem Cell Institute seeks to understand the biology of stem cells and translate basic research into new regenerative therapies.
As of 2008, The Rosenstiel School of Marine and Atmospheric Science receives $50 million in annual external research funding. Their laboratories include a salt-water wave tank, a five-tank Conditioning and Spawning System, multi-tank Aplysia Culture Laboratory, Controlled Corals Climate Tanks, and DNA analysis equipment. The campus also houses an invertebrate museum with 400,000 specimens and operates the Bimini Biological Field Station, an array of oceanographic high-frequency radar along the US east coast, and the Bermuda aerosol observatory. The University of Miami also owns the Little Salt Spring, a site on the National Register of Historic Places, in North Port, Florida, where RSMAS performs archaeological and paleontological research.
The University of Miami built a brain imaging annex to the James M. Cox Jr. Science Center within the College of Arts and Sciences. The building includes a human functional magnetic resonance imaging (fMRI) laboratory, where scientists, clinicians, and engineers can study fundamental aspects of brain function. Construction of the lab was funded in part by a $14.8 million in stimulus money grant from the National Institutes of Health.
In 2016 the university received $161 million in science and engineering funding from the U.S. federal government, the largest Hispanic-serving recipient and 56th overall. $117 million of the funding was through the Department of Health and Human Services and was used largely for the medical campus.
The University of Miami maintains one of the largest centralized academic cyber infrastructures in the country with numerous assets. The Center for Computational Science High Performance Computing group has been in continuous operation since 2007. Over that time the core has grown from a zero HPC cyberinfrastructure to a regional high-performance computing environment that currently supports more than 1,200 users, 220 TFlops of computational power, and more than 3 Petabytes of disk storage.
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