Volcano Watch: How tephra deposits unlock the secrets of Kilauea volcano’s explosive past

Keanakako‘i Tephra from unit D in Kilauea south caldera wall; the lower portion of the tephra deposit has been smoothed with a scraper tool, making the surface look different from the portion above. a) finely laminated ash layers as well as a fine ash layer and a coarser layer with pumice grains, b) microscope photo of a dense, glassy ash grain from the fine lamination layers, c) microscope photo of a small pumice grain from the coarser layer, and d) well-preserved example of a fine ash layer with accretionary lapilli. (USGS photos by J. Schmith/Special to West Hawaii Today)
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I go to the summit of Kilauea most weeks to study the extent, thickness, and physical characteristics of a 400- to 500-year-old tephra deposit, the product of explosive eruptions and part of what is called the Keanakako‘i Tephra. The total deposit is up to 10 meters (30 feet) thick along the southern wall of Kilauea caldera, but it was created by fragment upon fragment of tephra falling to the ground from volcanic plumes rising out of the caldera.

As I work with my measuring stick, sampling kit, and notebook, I look at this timeline set in stone, and I try to envision a time when explosive eruptions were common at Kilauea summit.

The tephra deposit has many stories to tell. The lowest and therefore the oldest part contains thinly laminated coarse and fine layers of volcanic ash (particles up to 2 mm or 0.08 inches in size). The thin laminations tell me explosions were small, but frequent. I visualize a cone in the caldera that expels small plumes of ash only minutes apart with loud blasts.

i look closer at the tiny individual fragments that make up the layers. They are glassy and dense with straight sides. This is common for ash generated by explosions where hot magma comes into contact with water at the surface of the volcano. So maybe the vent was submerged under a crater lake? I visualize the cone barely poking above the water surface.

Above the laminations the deposit changes. Several centimeters (a couple of inches) of fine ash that clumps together in 3–5 mm (0.12–0.20 inches) spheres—accretionary lapilli! The finer size of the ash suggests that the explosions got more intense, tearing the magma apart more efficiently, and the clumping is often associated with wet air. I visualize a denser plume rising from the vent with a louder blast. Does the water vapor come from the crater lake that I was imagining? Or was it raining?

if I had been at this very spot at the time of the explosions, the air would have been thick with ash. Breathing would have been difficult, if not impossible. Later, the fine ash would have been picked up by the wind, scratching my eyes and irritating my nose and lungs. Little time elapsed between the smaller explosions and these more intense ones, because all the fine layers are intact and have not been disturbed by wind erosion, which would likely happen within hours or a few days at Kilauea summit.

The laminated layers return above the fine ash, so the intensity of the explosions went back down, but then another change happened. Not only ash, but also larger, dense, glassy grains (2-6 mm, 0.08-0.24 inches) appear in a coarser layer about 20 mm (0.79 inches) thick, as does a new component: pumice!

Pumice was long thought to only come out of highly explosive volcanoes like Mount St. Helens — but here it is at Kilauea! Pumice grains are pieces of broken magma foam that forms by intensive bubbling of magmatic gas before eruption. Pumice is very different in nature from those dense fragments that make up the rest of the deposit, so why is it here?

Pumice can be generated in lava fountains, so maybe a fissure opened outside the crater lake? But then why are the dense grains getting larger at the same time? Was the magma rising faster through the water, resulting in less time for interaction? Or did Kilauea supply more magma to the eruption generating a higher plume? I know I can’t answer those questions from this one location alone. I need to see how the different layers are distributed in the area around Kilauea caldera.

So, after measuring, sampling, sketching, and making notes about the Keanakako‘i Tephra deposit at this site, I continue my journey to other locations hoping to unlock more secrets of Kilauea’s explosive past.

Volcano activity updates

Kilauea volcano is erupting. its USGS Volcano Alert level is at WATCH. Over the past week, lava has continued to intermittently erupt from the western vent within Halema‘uma‘u crater. All lava is confined within Halema‘uma‘u crater in Hawaii Volcanoes National Park. Sulfur dioxide emission rates remain elevated and were last measured at approximately 3,200 tonnes per day (t/d) on April 6 during decreasing eruptive activity. Seismicity is elevated but stable, with few earthquakes and ongoing volcanic tremor. Summit tiltmeters show several minor deflation and inflation trends over the past week.

Mauna Loa is not erupting and remains at Volcano Alert Level ADVISORY. This past week, about 67 small-magnitude earthquakes were recorded below the summit and upper elevation flanks of Mauna Loa — the majority of these occurred at shallow depths less than 9 miles below sea level. GPS measurements show low rates of ground deformation over the past week. Gas concentrations and fumarole temperatures at both the summit and at Sulphur Cone on the Southwest Rift Zone have remained stable over the past week.

No felt earthquakes were reported in the Hawaiian Islands during the past week.

This week’s article was written by Johanne Schmith, a visiting scientist funded by the Carlsberg Foundation. Visit https://www.usgs.gov/observatories/hawaiian-volcano-observatory for past Volcano Watch articles, updates, photos, maps, recent earthquake info, and more. Email questions to askHVO@usgs.gov. Volcano Watch is a weekly article and activity update written by USGS Hawaiian Volcano Observatory scientists and affiliates.