Gas Plume during the 1985 eruption of Kīlauea, Hawaii blocks out the sun. This image was taken from Kīlauea summit during episode 32 of the Pu‘u ‘Ō‘ō eruption on the middle East Rift Zone of Kīlauea. USGS image by J.D. Griggs on April 22, 1985.
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Gas Plume during the 1985 eruption of Kīlauea, Hawaii
Gas Plume during the 1985 eruption of Kīlauea, Hawaii blocks out the sun. This image was taken from Kīlauea summit during episode 32 of the Pu‘u ‘Ō‘ō eruption on the middle East Rift Zone of Kīlauea. USGS image by J.D. Griggs on April 22, 1985.
Aerial view of waning lava fountain, Kilauea Volcano, 1985
Aerial view, from the east, of waning lava fountain from Pu'u 'O'o on Hawai'i Island's Kilauea Volcano. Taken at the end of eruption episode 32. Pu'u 'O'o rose 209 meters above the pre-1983 surface (928 meters above sea level).
Aerial view, from the east, of waning lava fountain from Pu'u 'O'o on Hawai'i Island's Kilauea Volcano. Taken at the end of eruption episode 32. Pu'u 'O'o rose 209 meters above the pre-1983 surface (928 meters above sea level).
Aerial View of Mauna Loa Volcano, Hawaii
USGS Hawaiian Volcano Observatory scientists monitor Mauna Loa, the largest active volcano on Earth. In this 1985 aerial photo, Mauna Loa looms above Kīlauea Volcano’s summit caldera (left center) and nearly obscures Hualālai in the far distance (upper right).
USGS Hawaiian Volcano Observatory scientists monitor Mauna Loa, the largest active volcano on Earth. In this 1985 aerial photo, Mauna Loa looms above Kīlauea Volcano’s summit caldera (left center) and nearly obscures Hualālai in the far distance (upper right).
Mount Jefferson in OR seen from the east.
Mount Jefferson in Oregon seen from the east.
Mount Jefferson in Oregon seen from the east.
Belknap Shield Volcano viewed from McKenzie Pass, OR.
Belknap Shield Volcano viewed from McKenzie Pass, Oregon. Photo by Lyn Topinka.
Belknap Shield Volcano viewed from McKenzie Pass, Oregon. Photo by Lyn Topinka.
Mount WA peak in central OR.
Mount Washington peak in central Oregon.
Mount Washington peak in central Oregon.
Mount St. Helens four years after the May 18, 1980 eruption—lava do...
Mount St. Helens four years after the May 18, 1980 eruption—lava dome in the crater and drainage channels development on flanks; view from Johnston Ridge.
Mount St. Helens four years after the May 18, 1980 eruption—lava dome in the crater and drainage channels development on flanks; view from Johnston Ridge.
Lava fountain 450 m (1,475 ft) high from Kīlauea Pu‘u ‘Ō‘ō eruption...
Lava fragments ejected by lava fountains are called tephra, a general term for all fragments, regardless of size, that are blasted into the air by explosive activity. A variety of terms are also used to describe specific types of fragments, including Pele's hair, Pele's tears, scoria, spatter, bombs, and reticulite.
Lava fragments ejected by lava fountains are called tephra, a general term for all fragments, regardless of size, that are blasted into the air by explosive activity. A variety of terms are also used to describe specific types of fragments, including Pele's hair, Pele's tears, scoria, spatter, bombs, and reticulite.
Lava fountain 450 m (1475 ft) high, Pu‘u ‘Ō‘ō. Dark plume includes ...
Low fountains in foreground erupting from a fissure that opened just before the main vent began to erupt.
Low fountains in foreground erupting from a fissure that opened just before the main vent began to erupt.
Crater and dome view of Mount St.Since Dec. 1980, eruptions of Moun...
Lava dome within Mount St. Helens crater grew between 1980 and 1986 as dacitic lava erupted from the vent. This photograph, taken in September 1984.
Lava dome within Mount St. Helens crater grew between 1980 and 1986 as dacitic lava erupted from the vent. This photograph, taken in September 1984.
Fireweed, growing in Mount St. Helens' devastated area, Summer 1985
Vegetation began reappearing as early as the summer of 1980 as many small trees and plants were protected by the snowpack on May 18. Seeds, carried by the wind or by animals, also entered the area and grew. By 1985, the ridges surrounding the volcano were covered with new growth.
Vegetation began reappearing as early as the summer of 1980 as many small trees and plants were protected by the snowpack on May 18. Seeds, carried by the wind or by animals, also entered the area and grew. By 1985, the ridges surrounding the volcano were covered with new growth.
Measurements of magnetic field surrounding the Mount St. Helens' dome
The strength of the magnetic field increased as the dome cooled and magnetic minerals formed. During the eruptions the strength usually changed rapidly as magma heated and deformed the dome.
The strength of the magnetic field increased as the dome cooled and magnetic minerals formed. During the eruptions the strength usually changed rapidly as magma heated and deformed the dome.
Three USGS geologists measure the distance across a crack on the cr...
The U.S. Geological Survey established both periodic and continuous 24-hour monitoring programs at Mount St. Helens to study and predict eruptions. In this slide, geologists used a steel tape to measure the distance across a crack on the crater floor. Widening of cracks was an indication that magma was rising and deforming the area, leading to an eruption.
The U.S. Geological Survey established both periodic and continuous 24-hour monitoring programs at Mount St. Helens to study and predict eruptions. In this slide, geologists used a steel tape to measure the distance across a crack on the crater floor. Widening of cracks was an indication that magma was rising and deforming the area, leading to an eruption.
Lava dome measurements of angles and slope distances using a theodo...
An increase in deformation rates is an indication that magma is slowly entering the dome. In the early 1980s deformation rates often reached 30 feet per hour (10 meters/hour) as magma rose and the dome expanded before extrusion started. During the winter months, the instrument stations often had to be dug out of the snow before measurements could be made.
An increase in deformation rates is an indication that magma is slowly entering the dome. In the early 1980s deformation rates often reached 30 feet per hour (10 meters/hour) as magma rose and the dome expanded before extrusion started. During the winter months, the instrument stations often had to be dug out of the snow before measurements could be made.
Lava production from these "2,900-m vents" decreased by 80% between...
Lava production from these "2,900-m vents" decreased from less than 100,000 m3 per hour on April 9 to about 20,000 m3 on April 13, which was the last full day of eruption. Active lava flows extended less than 2 km from the vents. Note two geologists for scale in lower right (in green flight suits). Mauna Loa summit in upper left.
Lava production from these "2,900-m vents" decreased from less than 100,000 m3 per hour on April 9 to about 20,000 m3 on April 13, which was the last full day of eruption. Active lava flows extended less than 2 km from the vents. Note two geologists for scale in lower right (in green flight suits). Mauna Loa summit in upper left.
Low lava fountains from 1984 Mauna Loa "2,900-m vents" signaled dec...
Lava production from these "2,900-m vents" began to decrease in late March but declined most rapidly between April 7 and 9 from about 300,000 m3 per hour to less than 100,000 m3 per hour. Photo taken at 9:09 a.m.
Lava production from these "2,900-m vents" began to decrease in late March but declined most rapidly between April 7 and 9 from about 300,000 m3 per hour to less than 100,000 m3 per hour. Photo taken at 9:09 a.m.
Lava channel blockage caused an overflow of the main lava channel l...
Blockage and overflow of main ‘A‘ā lava channel leading from the 2,900-m vents; note helicopter below the blockage. Large, floating debris of solidified lava (called lava boats) and debris from surface crusts sometime congregate at constrictions along the channel, causing blockages of the main channel.
Blockage and overflow of main ‘A‘ā lava channel leading from the 2,900-m vents; note helicopter below the blockage. Large, floating debris of solidified lava (called lava boats) and debris from surface crusts sometime congregate at constrictions along the channel, causing blockages of the main channel.
Slow-moving front of an advancing ‘A‘ā lava flow from 1984 Mauna Lo...
After repeated blockages and overflows of the main lava channel between April 5 and 8, the steady supply of lava to well-developed flow fronts below the 1,850-m level ceased. As the lowest flow fronts stagnated and the rate of eruption from the vents slowed, hazard concerns for Hilo diminished.
After repeated blockages and overflows of the main lava channel between April 5 and 8, the steady supply of lava to well-developed flow fronts below the 1,850-m level ceased. As the lowest flow fronts stagnated and the rate of eruption from the vents slowed, hazard concerns for Hilo diminished.
Lava flows from the 1984 eruption of Mauna Loa loom above the town ...
Lava flows from the 1984 eruption of Mauna Loa loom above the town of Hilo. Photograph taken near the Hilo airport on April 4.
Lava flows from the 1984 eruption of Mauna Loa loom above the town of Hilo. Photograph taken near the Hilo airport on April 4.
Lava fountains feed voluminous lava flows from 1984 eruption of Mau...
These are 19 km east of the original outbreak point that began within Moku‘āweoweo caldera about 36 hours earlier.
These are 19 km east of the original outbreak point that began within Moku‘āweoweo caldera about 36 hours earlier.
Aa lava flows erupting from Mauna Loa.
Aa lava flows erupting from Mauna Loa.
Aa lava flows erupting from Mauna Loa.