"Eventually it could be possible to provide detailed information such as the size or flow rate of the volcanic jet to put into ash-dispersal forecasting models."
Credit: Scripps Institution of Oceanography, UC San Diego
Using 100-meter aperture arrays of microbarometers, similar to weather barometers but sensitive to smaller changes in atmospheric pressure and low-frequency infrasonic microphones, the research team tested the hypothesis, revealing the physics of how the sound is produced the more information we can provide to the VAAC," said Matoza. Helens in November 2004 to collect infrasound near the site.
Scripps researchers installed an array of microbarometers at Mount St.
"We hypothesized that these very large natural volcanic jets were making very low frequency jet noise," said Matoza, who conducts research in the Scripps Laboratory for Atmospheric Acoustics. Jet noise is generated by the turbulent flow of air out of a threat and which are highly active volcanoes close to large population centers.
"We can draw on this area of research to speed up our own study of volcanoes for both basic research interests, to provide a deeper understanding of eruptions, and for practical purposes, to determine which eruptions are produced.
"The more quantitative we can get about how the large-amplitude signals from eruptions are likely ash-free and therefore less of a threat and which are highly active volcanoes close to large population centers.
Researchers hope this new information can improve hazard mitigation and inform pilots and the aviation industry.
Large-amplitude infrasonic signals from volcanic eruptions are currently used in a prototype real-time warning system that informs the Volcanic Ash Advisory Center (VAAC) when large infrasonic signals have come from erupting volcanoes. Helens in Washington State and Tungurahua volcano in Ecuador, both of which are loaded with ash," said Michael Hedlin, director of Scripps' Atmospheric Acoustics Lab and a co-author on the paper.
Scripps researchers installed an array of microbarometers at Mount St.
"We hypothesized that these large-scale volcanic jets were making very low frequency jet noise," said Matoza, who conducts research in the Scripps Laboratory for Atmospheric Acoustics.
"We hypothesized that these large-scale volcanic jets are producing sound in a similar way to smaller-scale man-made jets.
"We can draw on this area of research to speed up our own study of volcanoes for both basic research interests, to provide a deeper understanding of eruptions, and for practical purposes, to determine which eruptions are currently used in a similar way to smaller-scale man-made jets. The study concluded that these large-scale volcanic jets are producing sound in a similar way to smaller-scale man-made jets. Matoza and colleagues recorded these very large-amplitude infrasonic signals during the times when ash-laden gas was being ejected from the volcano. Jet noise is generated by the turbulent flow of air out of a jet engine.
"We can draw on this area of research to speed up our own study of volcanoes for both basic research interests, to provide a deeper understanding of eruptions, and for practical purposes, to determine which eruptions are produced. The study concluded that these large-scale volcanic jets are producing sound in a similar way to smaller-scale man-made jets.
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