The ongoing eruption at Kilauea Volcano’s summit began March 19, 2008. Since that time, Hawaii Island residents have had to cope with the challenges of increased vog and its effects.
The ongoing eruption at Kilauea Volcano’s summit began March 19, 2008. Since that time, Hawaii Island residents have had to cope with the challenges of increased vog and its effects.
On the other hand, the glowing lava lake within the summit vent provides a beautiful sight, drawing hundreds of visitors to Hawai‘i Volcanoes National Park nightly. When the lava lake briefly rose and spilled onto the floor of Halema‘uma‘u Crater in April and May 2015, it showed itself as a vivid reminder of Kilauea’s dynamic nature.
While noting its eighth anniversary this month, it’s also worth reflecting on what Kilauea’s summit eruption has taught us. One remarkable aspect of the eruption is the lava lake. There are only a few lava lakes on Earth, and the Halema‘uma‘u lava lake is the second largest — only slightly smaller than that in Nyiragongo Volcano in the Democratic Republic of the Congo.
Kilauea’s lava lake is a rare opportunity to study the volcano’s dynamic magmatic system. So, what have we learned?
Lava lakes are often called “windows” into a volcano’s deep magmatic system, because they literally are part of a direct pipeline from the deep magma chamber to the surface. What happens in the deep magmatic system — like changes in magma supply rate or internal pressure — should be reflected in the lava lake at the surface. USGS Hawaiian Volcano Observatory scientists and their collaborators have closely studied Kilauea’s summit lava lake, and now have several years of detailed observations to test this idea.
Does the summit lava lake actually provide insights into the unseen magmatic system below? Research is still in progress, but results thus far indicate that the answer is “yes and no.”
If you follow HVO’s daily eruption updates, or view Kilauea’s summit webcams, you can see that the summit lava lake level changes frequently. And if you follow closely, you probably have noticed that when summit tiltmeters show deflationary tilt, the lava lake drops, while inflationary tilt corresponds to a rising lava lake. Tiltmeters essentially measure pressure within the summit magma chamber, and so, inflationary tilt means higher pressure and deflationary tilt indicates lower pressure.
The close relationship between the summit lava lake level and ground tilt is remarkable, because it demonstrates that the lake behaves like a pressure gauge of the deeper magma chamber — akin to a giant liquid barometer.
This is an important example of how the lava lake is, indeed, a window into the state of the deep magma chamber.
Now, let’s look at an example of when this “window” idea appears to break down.
The lava lake surface constantly flows from one side of the lake, where magma rises from depth, to the opposite side of the lake, where it sinks. At first glance, this seems to directly show the process of magma circulating between the deep magma chamber and the lake surface, like an enormous lava lamp. While this might be true most of the time, observations show that the lava lake’s surface flow is often interrupted by spattering and rockfalls, which completely change the speed and direction of the lake surface circulation.
Data show that spattering and rockfalls do not seem to have a deep trigger. Instead, they reflect shallow processes near the lava lake’s surface. These sporadic changes in the lake’s circulation are examples of how the lava lake reflects near-surface processes, and do not always indicate processes in the deep magma system.
Beyond these insights, a remaining question is how long the summit eruption will last. Unfortunately, there is no definitive data we can gather to answer this question.
The best we can do is look at Kilauea’s recent history. A lava lake was frequently present at Kilauea’s summit for more than a hundred years — from the early 1800s into the early 1900s.
This persistence suggests that Kilauea’s summit lava lakes have the potential to last for decades. With the East Rift Zone’s Pu‘u ‘O‘o eruption reaching its 33rd anniversary in January 2016, Kilauea Volcano is remarkable among the world’s volcanoes for having two long-term, concurrent eruptions.
While having such an active volcano in our backyard presents both benefits and challenges, Kilauea will likely remain one of Earth’s most outstanding teachers of volcano science for years to come.
Volcano activity updates
Kilauea continues to erupt at its summit and East Rift Zone. During the past week, the summit lava lake was relatively stable, with the lake level around 30-33 meters (98–108 feet) below the vent rim within Halema‘uma‘u Crater. On the East Rift Zone, scattered lava flow activity remains within about 6.7 kilometers (4.1 miles) of Pu‘u ‘O‘o and is not currently threatening nearby communities.
Mauna Loa is not erupting. Seismicity remains elevated above long-term background levels.
GPS measurements show continued deformation related to inflation of a magma reservoir beneath the summit and upper Southwest Rift Zone of Mauna Loa, with inflation recently occurring mainly in the southwestern part of the magma storage complex.
One earthquake was reported felt on Hawaii Island this past week. On Monday, at 12:29 p.m., a magnitude-3.5 earthquake occurred 4.7 kilometers (2.9 miles) west of Glenwood at a depth of 13.8 kilometers (8.6 miles).
Visit the HVO website (http://hvo.wr.usgs.gov) for past Volcano Watch articles, Kilauea daily eruption updates, Mauna Loa weekly updates, volcano photos, recent earthquakes info, and more; call for summary updates at 967-8862 (Kilauea) or 967-8866 (Mauna Loa). Email questions to askHVO@usgs.gov.
Volcano Watch (http://hvo.wr.usgs.gov/volcanowatch/) is a weekly article and activity update written by scientists at the U.S. Geological Survey`s Hawaiian Volcano Observatory.