Volcano Watch — Eaton moves HVO forward

Subscribe Now Choose a package that suits your preferences.
Start Free Account Get access to 7 premium stories every month for FREE!
Already a Subscriber? Current print subscriber? Activate your complimentary Digital account.

Volcano Watch is a weekly article and activity update written by scientists at the U.S. Geological Survey’s Hawaiian Volcano Observatory.

From 1912 to 1950, HVO used mechanical seismometers called tromometers (derived from “tremble”) that recorded the vibrations sensed by a long, suspended boom. Imagine how an unlatched gate would swing back and forth in response to an earthquake, and you have a basic idea how these early instruments worked.

Recordings were made as the end of the boom scratched a line on a smoke-coated paper on a cylindrical rotating drum. The instruments were quite large, consisting of a vertical post about 5 feet high, to which a 3-foot, or longer, boom was attached on one end and suspended by a wire and damped with a weight exceeding 100 pounds on its free end.

These mechanical tromometers had many limitations. The booms were easily dismantled by large earthquakes and had to be reassembled before operation could resume. They had low sensitivity and the HVO tromometers were able to detect earthquakes of only magnitude-3.0 or greater.

In 1950, HVO had put an electromagnetic seismograph into operation as the first step in an upgrade of the network. The hiring of Jerry Eaton, a new seismology Ph.D. from University of California at Berkeley, was the second step. He was the seventh seismologist to be stationed at Kilauea, but the first who was familiar with the new electromagnetic seismographs that were destined to replace the mechanical tromometers.

The electromagnetic seismographs were based on a solenoid, a cylindrical coil of wire within which a metallic cylindrical core could move. Oscillation of the metal core within the wire coil during an earthquake would generate an electrical current in the wire which could be recorded in several ways. The electromagnetic seismograph had many benefits: They were much smaller, lighter, and their signals could be amplified to be 1,000 times more sensitive than the mechanical tromometers.

The electromagnetic seismograph could also be tuned to better detect the smaller earthquakes associated with Hawaiian volcanism. Eaton experimented with a few changes, using seismographs installed in his basement. HVO machinists used Eaton’s designs to modify an existing electromagnetic seismograph, dubbed HVO-1. When Jerry put an HVO-1 seismograph into operation alongside the older electromagnetic seismograph, “it recorded between five and 10 times as many earthquakes.” The network of electromagnetic seismometers was able to record 100 times more earthquakes and allowed the identification of families of earthquakes as they occurred through space and time.

But Eaton wasn’t done. He saw the value of monitoring ground tilt to forecast volcanic eruptions, but also saw the limitations in HVO’s 1950 methods, using the wanderings of the mechanical tromometer booms for the measurement.

Adapting a Japanese design, he and the HVO machinists built water-tube tiltmeters out of artillery-shell casings and garden hose. When completed and installed, they tracked the tromometer tilt very well, validating the concept.

After setting up a small network of these tiltmeters to complement the expanding seismic network at Kilauea summit, Eaton was able to locate and track the subsurface magma injections, along with earthquakes, that led to the 1959 eruption of Kilauea Iki.

In the eight years Eaton was at HVO, he reinvigorated seismic and geodetic monitoring and, for his efforts, was able to propose the first comprehensive model for Kilauea’s eruption mechanism.

Next week, the final Volcano Watch article in this series will complete the story of HVO’s first 100 years.

This week’s Volcano Awareness Month activities include a presentation about Mauna Loa in the Hawaii Volcanoes National Park’s Kilaua Visitor Center on Tuesday, a talk about HVO’s history of earthquake monitoring during the past 100 years at the University of Hawaii at Hilo on Thursday, and daily guided hikes in the park. HVO scientists will also give a talk about Kilauea and Mauna Loa volcanoes at the Lyman Museum in Hilo Monday evening, and will provide a display about, and be available to answer questions about, Hawaiian volcanoes at the annual Onizuka Science Day at UH-Hilo on Saturday.

Details about these activities are available at hvo.wr.usgs.gov and by calling 967-8844.

Kilauea activity
update

A lava lake present within the Halema’uma’u Overlook vent during the past week resulted in night-time glow that was visible from the Jaggar Museum overlook.

The lake, which is about 330 to 410 feet below the floor of Halema’uma’u Crater and is visible by HVO’s webcam, rose and fell slightly during the week in response to a series of large deflation-inflation cycles.

On Kilauea’s east rift zone, surface lava flows that were active in the upper part of the flow field, about 2.2 miles southeast of Pu’u ‘O’o, paused by Jan. 14, and remained inactive for the next few days.

Breakouts on the upper flow field resumed on Tuesday, but diminished again within a day.

These fluctuations are controlled by varying lava supply at the vent due to summit deflation-inflation cycles. The flow field on the coastal plain remains inactive after activity stalled there three weeks ago, and the West Ka’ili’ili ocean entry is still inactive.

Occasional short lava flows have been observed over the past week within Pu’u ‘O’o crater.

No earthquakes beneath Hawaii Island were reported felt this past week.

Visit the HVO website (http://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.