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Volcano Watch: How do lava flows cool and how long does it take?

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

This ‘a‘ā flow erupted from fissure 8  on Kīlauea Volcano’s lower East Rift Zone on June 1, 2018, shows how the interior of a lava flow remains incandescently hot even though surface cooling forms a crust of solid rubble. Based on studies of lava flow cooling rates, it will take more than 130 days for a flow this thick (about 4.5 m, or 15 ft) to cool to a temperature of about 200 degrees Celsius (290 degrees Fahrenheit). USGS photo by A. Lerner.

This ‘a‘ā flow erupted from fissure 8  on Kīlauea Volcano’s lower East Rift Zone on June 1, 2018, shows how the interior of a lava flow remains incandescently hot even though surface cooling forms a crust of solid rubble. Based on studies of lava flow cooling rates, it will take more than 130 days for a flow this thick (about 4.5 m, or 15 ft) to cool to a temperature of about 200 degrees Celsius (290 degrees Fahrenheit). USGS photo by A. Lerner.

Since the end of the 2018 lower East Rift Zone (LERZ) eruption on KÄ«lauea Volcano, questions have surfaced concerning how long it will take for the new lava flows to solidify. This is a difficult question to answer, because the initial eruptive temperatures along with many different factors can influence the rate of cooling.

Eruptive lava temperatures of the 2018 LERZ eruption reached a maximum of approximately 1140 degrees Celsius (2080 degrees Fahrenheit). When the entire flow cools below about 1000 degrees Celsius (1800 degrees Fahrenheit), it has solidified, but the interior is still very hot.

Arguably the most influential factor determining how fast lava cools is the thickness of the flow. Other factors include heat loss from both the top (to the atmosphere) and bottom of a flow (into the ground). Contributing to heat loss at the flow’s surface are air temperature, rainfall, and wind.

The initial contact between a lava flow, the air above it, and ground surface below it, quickly hardens the outer crust (top and bottom) of the flow. This is apparent in the silvery crust that forms on active pāhoehoe flows and the rubbly clinker that surrounds active ‘a‘ā flows. As the crust cools and thickens, it retains heat within the flow’s interior. This is because the crust is a good insulator, meaning it poorly conducts heat—similar to how an insulated thermos keeps liquid inside it hot.

After the initial formation of crust, the flow continues to lose heat through radiation and conduction, facilitated by wind and rain. As rain water percolates into cracks in the flow’s surface and encounters the hot interior, it produces steam, forming the billowy white plumes often seen over active (or recently active) flows. This steaming can persist for decades, long after the lava has solidified, depending on the thickness of the flow and the temperature of its interior.

Based on a study of crustal cooling of pāhoehoe lava flows in Kalapana erupted from the East Rift Zone Kupaianaha vent in 1990, we can estimate the solidification time for the 2018 LERZ flows. Because the equation only looks at cooling of the lava flow’s upper crust, the basal crust thickness is assumed to equal 70 percent of the upper crust according to this study.

The Kalapana measurements were made on thin pāhoehoe flows, but most of the 2018 LERZ lava is ‘a‘ā. But, because the core of each flow type should cool at similar rates, we are basing 2018 cooling rates on the 1990 study. Also, of note, the flows studied in 1990 were much thinner with shorter cooling rates and may not account for long-term changes in wind and rain patterns.

Preliminary analyses of the 2018 LERZ eruption flow thicknesses, suggest that the average flow thickness is around 10–15 m (33–50 ft). Based on the cooling rate calculation, it could take roughly 8 months to 1.5 years for flows of these thicknesses to solidify.

Solidification of flows ranging 20–30 m (65–100 ft) thick could take about 2.5–6 years. The thickest LERZ flows on land, which are approximately 55 m (180 ft) thick, may take roughly 20 years to reach a completely solid state.

Because flow thickness, wind speeds, rainfall amounts, air and ground temperatures, and other factors all affect lava cooling rates, there is a range of uncertainty on how long the interior of a flow remains liquid. For example, after the 1959 KÄ«lauea Iki eruption, the approximately 135 m (440 ft) deep lava lake took about 35 years to completely solidify, and the interior of the lake could still be hot enough today that the rock is incandescent. This is why, on rainy days, you can see steam rising from the KÄ«lauea Iki crater floor, as well as the KÄ«lauea caldera floor.

With flow crust being such an efficient insulator, it can take years to decades for lava within thick flows to solidify. It takes much longer for the flow to cool to ambient temperatures.

Next week’s Volcano Watch will address in more detail the thicknesses of lava flows from the 2018 LERZ eruption.

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