Monday, September 15, 2008
Lava Butte
Thursday, September 11, 2008
Newberry Volcano
Getting to see Newberry Volcano was fantastic! The drive was about 3 hrs from Portland but definitely worth the trip. Newberry Volcano lies about 40 miles east of the Cascade Range just south of Bend, Oregon. Unlike the steep, impressive cone-shaped stratovolcanoes of the Cascades, Newberry Volcano forms a broad, low "shield" shape (hence the name shield volcano) approximately 40 miles long and 20 miles wide. This cross section from Alt and Hyndman's Roadside Geology of Oregon (1978) does a good job of showing how inconspicuous Newberry is on the landscape:
The Newberry crater is now collapsed, leaving a caldera 8 miles wide with two nice little lakes on either side of an obsidian flow. I was expecting to see almost exclusively basalt at a shield volcano, but the Newberry volcanic complex actually has a wide range of extrusive rock types.
MacLeod et al. (2006) does a good job of summarizing the petrology of the volcano, though it is much more information than the casual reader would be interested in. The younger lava flows are roughly 6,000 years old and tend to have slightly higher silica contents (basaltic andesites). The older lava flows tend to be more mafic, but they are not as well exposed as the younger flows, so most chemical studies show a greater proportion of basaltic andesites than is probably representative.
MacLeod et al. (2006) does a good job of summarizing the petrology of the volcano, though it is much more information than the casual reader would be interested in. The younger lava flows are roughly 6,000 years old and tend to have slightly higher silica contents (basaltic andesites). The older lava flows tend to be more mafic, but they are not as well exposed as the younger flows, so most chemical studies show a greater proportion of basaltic andesites than is probably representative.
After the crater collapsed (as the magma chamber was emptied) episodes of pumice, ash, obsidian and rhyolite took place.
The Big Obsidian Flow, inside the caldera, is really something to see. In total, they are about 100 feet thick. If you want to collect some obsidian samples you can check out the rockhound quarries at Glass Buttes. Obsidian, or volcanic glass as it is commonly called, has the chemical composition of a high-silica rhyolite. The Roadside Geology authors pose an interesting question: if obsidian really forms as glass because it cooled too rapidly for crystals to form, then how do we explain the Big Obsidian Flow? Some of the individual flows are several feet thick in places. How would this cool so quickly as to prevent rhyolite from forming? Their explanation is that obsidian lavas contain very little water; too low for crystals to form. Seems plausible...however, some ingrained ideas are hard to part with.
NOTE: I wouldn't recommend sandels or open-toed shoes here.
A larger question in my mind is this: it appears that the Newberry Volcano gradually produced more silicic lavas throughout its lifespan. It's last eruption was a thick, viscous rhyolite magma. The volcano appears to be dormant though that's not certain. Is this evolution typical of other shield volcanoes in the area? I suspect it is. Can the compositional variations we see solely be the result of differentation in the magma chamber? Ah, something to sleep on.
References:
Alt D. and Hyndman D., 1978, Roadside Geology of Oregon, Mountain Press Publishing Co., p. 219-223
MacLeod N., Sherrod D., Chitwood L. and McKee E., 2006, Newberry Volcano, Oregon, USGS Geological Society Circular 838, http://www.nps.gov/history/history/online_booke/geology/publications/
The Big Obsidian Flow, inside the caldera, is really something to see. In total, they are about 100 feet thick. If you want to collect some obsidian samples you can check out the rockhound quarries at Glass Buttes. Obsidian, or volcanic glass as it is commonly called, has the chemical composition of a high-silica rhyolite. The Roadside Geology authors pose an interesting question: if obsidian really forms as glass because it cooled too rapidly for crystals to form, then how do we explain the Big Obsidian Flow? Some of the individual flows are several feet thick in places. How would this cool so quickly as to prevent rhyolite from forming? Their explanation is that obsidian lavas contain very little water; too low for crystals to form. Seems plausible...however, some ingrained ideas are hard to part with.
NOTE: I wouldn't recommend sandels or open-toed shoes here.
A larger question in my mind is this: it appears that the Newberry Volcano gradually produced more silicic lavas throughout its lifespan. It's last eruption was a thick, viscous rhyolite magma. The volcano appears to be dormant though that's not certain. Is this evolution typical of other shield volcanoes in the area? I suspect it is. Can the compositional variations we see solely be the result of differentation in the magma chamber? Ah, something to sleep on.
References:
Alt D. and Hyndman D., 1978, Roadside Geology of Oregon, Mountain Press Publishing Co., p. 219-223
MacLeod N., Sherrod D., Chitwood L. and McKee E., 2006, Newberry Volcano, Oregon, USGS Geological Society Circular 838, http://www.nps.gov/history/history/online_booke/geology/publications/
Friday, September 5, 2008
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