Boulder Park Explained

Boulder Park National Natural Landmark, of Douglas County, Washington, along with the nearby McNeil Canyon Haystack Rocks and Sims Corner Eskers and Kames natural landmarks, illustrate well-preserved examples of classic Pleistocene ice stagnation landforms that are found in Washington. These landforms include numerous glacial erratics and haystack rocks that occur near and on the Withrow Moraine, which is the terminal moraine of the Okanogan ice lobe.[1] [2]

Geomorphology

Boulder Park is located on the Waterville Plateau of the Columbia Plateau in north central Washington state in the United States. It is a broad, dish-shaped upland basin that overall dips gently northward. The Waterville Plateau extends east from Columbia River to the Grand Coulee. This plateau is underlain by Columbia River Basalt that is covered by a discontinuous blanket of 14,000 to 20,000 year-old glacial deposits.[1] [2]

This park lies about 6km (04miles) northeast and 17km (11miles) north of the arcuate ridge of the Withrow Moraine. It marks the southern, 17,000 year-old terminus of the Okanogan ice lobe and southern margin of the Cordilleran Ice Sheet. Boulder Park and adjacent areas is covered by a discontinuous blanket of gravelly, sandy loam glacial till. These glacial deposits overlie and partially/completely fill Moses Coulee, a paleochannel cut by a pre-Wisconsin megaflood that predated the Last Glacial Maximum. It was cut by older Spokane Floods at a time prior to when the Okanogan ice lobe partially covered the Waterville Plateau during most of the last of the Last Glacial Maximum. At its maximum extent, this ice lobe was up to 300m (1,000feet) thick and 40km (30miles) wide. It effectively blocked most of the Columbia River Valley and created Glacial Lake Columbia.[2] [3] [4]

The boulders for which this National Natural Landmark is named consist of glacial erratics and boulders known locally as haystack rocks that were transported southward by the Okanogan ice lobe of the Cordilleran ice sheet. The glacial erratics consist largely of granodiorite and gneiss that were transported southward. Haystack rocks consist of locally derived basaltic boulders. Because haystack rocks are identical to the local bedrock, they by definition cannot be classified as glacial erratics. Haystack rocks are blocks of basalt ripped from the entablature of the Columbia River Basalt Group by glacial ice of the Okanogan ice lobe. Preferential weathering along the joints of the entablature results in piles of talus, which together with the weathered erratics, that from a distance look like black haystacks. Some haystack rocks, e.g. Yeager Rock, are the size of large houses. The boulders provide important evidence for glacial erosion and transport, as well as marking the direction of movement and the terminus of the Okanogan ice lobe and the southern margin of the Cordilleran ice sheet during the Last Glacial Maximum.[2] [4] [5]

Underlying the glacial deposits of the Okanogan ice lobe and outcropping, where it is absent, is the middle Miocene, Priest Rapids Member of the Wanapum Basalt. Within the area of this park, it consists of grayish-black, fine- to coarse-grained basalt lava flows that contain scattered, fine-grained phenocrysts of either plagioclase or plagioclase and olivine. The Wanapum Basalt is part of the late Miocene and early Pliocene Columbia River Basalt Group. This group covers parts of the states of Washington, Oregon, and Idaho in the United States of America. It forms a large igneous province that covers an area of 163,700 km2 (63,000 mile2) of the Pacific Northwest with an estimated volume of 174,300 km3 of basalt lava and other volcanics. Eruptions were most vigorous between 17 and 14 million years ago, when over 99% of the basalt was released. Less extensive eruptions continued between 14 and 6 million years ago.[2] [3]

See also

External links

Photo gallery

Notes and References

  1. Book: Mueller, Marge & Ted. Fire, Faults and Floods. University of Idaho Press, Moscow, Idaho. 1997. 0-89301-206-8. registration.
  2. Bjornstad, B., and Kiver, E., 2012, On the Trail of the Ice Age Floods: The Northern Reaches: A geological field guide to northern Idaho and the Channeled Scabland. Keokee Books, Sandpoint, Idaho. 480 pp.
  3. Gulick, C.W., and M.A. Korosec (1990) Geologic map of the Banks Lake 1:100,000 quadrangle, Washington. Open File Report 90-6. Seattle, Washington, Washington Division of Geology and Earth Resources. 20 p., 1 pl.
  4. Easterbrook, D.J. (2003) Cordilleran Ice Sheet Glaciation of the Puget Lowland and Columbia Plateau, and alpine glaciation of the North Cascade Range. in Swanson, T.W., ed., Western Cordillera and Adjacent Areas. Field Guide 4, Boulder, Colorado, Geological Society of America. p. 137-157
  5. Cheney, E.S. (2009) Floods, Flows, Faults, Glaciers, Gold and Gneisses, From Quincy to Chelan to Wenatchee, June 13–14, 2009. Society Field Trips in Pacific Northwest Geology Field Trip Guidebook 24. Seattle, Washington, Northwest Geological Society. 44 p.