When William Ellis, the first Western visitor to the summit of Kilauea, looked out over the broad and deep caldera in 1823, he noted it “had been recently filled with liquid lava … and had, by some subterranean canal, emptied itself into the sea or upon the lower land on the shore.” He was repeating an inference that had already been made by early Hawaiians — magma drains from the summit to vents lower on the volcano’s flank.
When William Ellis, the first Western visitor to the summit of Kilauea, looked out over the broad and deep caldera in 1823, he noted it “had been recently filled with liquid lava … and had, by some subterranean canal, emptied itself into the sea or upon the lower land on the shore.” He was repeating an inference that had already been made by early Hawaiians — magma drains from the summit to vents lower on the volcano’s flank.
This simple and intuitive association has powerful implications for understanding Kilauea. Most importantly, it means there is a fluid connection from the rift zone to the summit during rift zone eruptions. When lava pours out of a rift zone vent, it drains magma from the summit magma chamber. Since Ellis’ visit, many subsequent eruptions have reinforced this idea and, in modern times, sensitive geophysical instruments have measured the process.
Perhaps the best way of tracking the fluid connection between the summit and rift zone would be to simultaneously measure the lava level at each location through time. But until recently, there simply weren’t any extended periods of simultaneous eruptions at the summit and rift zones — at least during the written historical period. The last four years, however, mark the first time in the past 500 years of long-term, simultaneous eruptions at the summit and rift zone. They provide the first opportunity for continuous observation of the lava level and, thus, the fluid connection, between the summit and the rift zones.
From 2011 to today, scientists have measured the level in the lava lake in Halemaumau at the summit and Puu Oo crater on the east rift zone. During this time, three major eruptive events disrupted the system: the March 2011 Kamoamoa eruption, the August 2011 Puu Oo draining and the September 2011 fissure openings.
Overall, the lava levels in Halemaumau and Puu Oo closely followed one another, exhibiting the same peaks and troughs. Three sharp drops in lava level, manifested at both locations, resulted from the three eruptive events that depressurized the entire magmatic system. These simple measurements demonstrate a good “hydraulic” connection between the two vents.
Although these two vents show the same fluctuations, the lava level in Halemaumau is, on average, about 260 feet higher than the lava level in Puu Oo at any given moment. If there is a good hydraulic connection, why don’t these lava levels equilibrate at the same elevation? In short, the answer may be friction. Water moving through pipes in your house, for instance, dissipates energy when it flows through bends, valves or fittings, because frictional forces effectively lessen the pressure in the fluid. If your home plumbing system has too many of these twists and turns, so much energy will be dissipated you’ll have weak water pressure at the faucet. This effect, called hydraulic head loss, is probably occurring in the conduit to the east rift zone, as well.
What are some implications of the hydraulic connection between the summit and east rift zone? First, the lava level provides another way — along with tilt, GPS and seismicity — to track the pressure in the summit-to-east rift zone plumbing system, helping scientists anticipate new events. Periods when the lava level is very high in the system have preceded major changes in the east rift zone eruption, such as intrusions and new fissures, presumably because of increased system pressure.
Second, a hydraulic connection means changes can be transmitted in either direction in the system. When magma supply at the summit increases, it moves downrift and increases the eruption rate at the east rift zone. Conversely, in August 2011, scientists saw a drainage of Puu Oo crater that was felt back at the summit, or uprift, triggering partial drainage of the Halemaumau lava lake.
There are broader implications for hazards, as well. Understanding the amount that summit lava levels drop during rift zone eruptive changes can help scientists understand the likelihood of powerful explosive eruptions at the summit. These explosions are thought to be triggered by lava draining to sufficiently low elevations that groundwater can infiltrate the hot magmatic system. This work is ongoing, but it shows hydraulic principles can help shed light on volcanic “plumbing” systems.
Kilauea activity update
A lava lake within the Halemaumau Overlook vent resulted in nighttime glow visible from the Jaggar Museum overlook during the past week. The lake has been about 200 to 260 feet below the floor of Halemaumau Crater and visible by Hawaiian Volcano Observatory’s webcam through much of the last month. This past week, the level fluctuated slightly because of several deflation-inflation cycles at the summit.
On Kilauea’s east rift zone, surface lava flows on the pali and coastal plain continued to be active. Over the past week, the flow front has advanced little and has lingered near the boundary of Hawaii Volcanoes National Park about 0.6 mile from the coastline; there was no active ocean entry. Within Puu Oo, a lava pond was active in the eastern portion of the crater.
Visit the HVO website at hvo.wr.usgs.gov for detailed Kilauea and Mauna Loa activity updates, recent volcano photos, recent earthquakes and more; call 967-8862 for a Kilauea summary; email questions to askHVO@usgs.gov.
Volcano Watch is a weekly article and activity update written by scientists at the U.S. Geological Survey’s Hawaiian Volcano Observatory.