Categorized | Featured, Sci-Tech, Volcano

Volcano Watch: Why is the 2018 lava still so hot?

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

Two HVO geologists document road cutting activities on HWY 132 on August 7, 2019. One geologist is taking visual photographs while another geologist is taking thermal photographs to make a tandem pair for comparison. The temperature of the solidified lava was measured to 425° C (800° F) at the digging site. Photograph by USGS geologist K. Mulliken.
Two HVO geologists document road cutting activities on HWY 132 on August 7, 2019. One geologist is taking visual photographs while another geologist is taking thermal photographs to make a tandem pair for comparison. The temperature of the solidified lava was measured to 425° C (800° F) at the digging site. Photograph by USGS geologist K. Mulliken.

As roads are recut into Kīlauea’s 2018 lava flow field, many have been surprised at how hot the lava remains under the surface, even though it is solidified. Why is it still so hot? The short and simple answer is that lava insulates itself very well.

Since last writing about this topic on February 28, 2019, “Volcano Watch” article, we now have more accurate calculations of lava thickness, cooling times, and the relative proportions of the internal molten core to the exterior solid crust for Kīlauea’s 2018 lava flow field.

Previous work by Hawaiian Volcano Observatory (HVO) scientists published in 1994 measured the cooling rate of pāhoehoe lava at Kalapana. They found that the upper crust of a basalt lava flow grows thicker as a function of the square root of time. In other words, the lava flow crust grows more slowly with time. Therefore, thicker lava flows will take longer to become completely solid.

Lava erupts from Kīlauea at a temperature of 1150° C (2100° F). In 1917, Thomas Jaggar published results from the then-active Halema‘uma‘u lava lake that indicated basalt can remain molten at temperatures as low as 750–850° C (1380–1560° F). For the calculations here, the crust is considered solid when it is below 850° C (1560° F) and crust is viscoelastic (semi-solid or malleable) at 850–1070° C (1560–1950° F).

Additional insight comes from previous HVO studies of active lava lakes in Kīlauea Iki, Makaopuhi, and ‘Alae craters. By drilling into the cooled upper crusts of lava lakes within these craters, scientists documented that solidification takes decades—specifically the 44-m (140 ft)-thick 1959 Kīlauea Iki lava lake took about 35 years to fully solidify. Today, its core is still hotter than 540° C (1,000° F).

Therefore, although the top surface of Kīlauea’s 2018 lava flows are already solid and cool to the touch, just beneath the surface is still very hot.

Unmanned Aircraft System (UAS) mapping in 2018 helped HVO create a lava flow thickness map. This map indicates that at the intersection known as “Four Corners” there is approximately 15 m (50 ft) of lava. Using this value and the equations from the 1994 study of the Kalapana lava flows, we can calculate how much of the 2018 flows have solidified.

Over the 14 months since the end of the eruption last year, the upper 7.8 m (24 ft) and lower 5.5 m (18 ft) at “Four Corners” should already be solidified crust, and the middle 1.7 m (5.5 ft ) should still be malleable.

It will take about 3 more years for the remaining 1.7 m (5.5 ft ) of malleable lava over the “Four Corners” intersection to reach 850° C (1560° F) and be completely solid.

When construction of new roads in the area expose hot temperatures just below the surface, the lava cooling profile is effectively reset. The newly-exposed surface will quickly lose heat, as if it were the original cooling surface.

This matches recent observations by road-construction crews, who noticed hot rocks being exposed at a road cut along HWY 132. HVO geologists confirmed this in August, when temperatures of 425° C (800° F) were measured at the newly-cut road site. Hot temperatures will remain several feet below the surface for now and will likely generate steam when there is rain.

Lava retains heat so well that thick flows take years to decades to completely solidify, and even longer to cool off. The UAS lava-flow thickness map indicates that over Kapoho Bay, the flow is over 50 m (160 ft) thick. The maximum thickness of 250 m (820 ft) is located east of the bay in an area that was formerly offshore. At both locations, the solid crusts will be the same thickness as at “Four Corners”, but the viscoelastic layer will be 4.7 m (15 ft). A thick molten inner core should exist within the ‘a‘ā flow delta and have a thickness of 32 m (105 ft) in the bay and an astonishing 232 m (761 ft) at the eastern area of maximum thickness.

Although Kīlauea’s 2018 eruption ended 14 months ago, it will be years before the lava flows emplaced on land are entirely solidified below 850° C (1560° F), and over a century before the 250-m (820 ft)-thick area offshore fully solidifies.

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