Jump to content

Nuʻuanu Slide

From Wikipedia, the free encyclopedia
(Redirected from Nu'uanu Slide)
Nuʻuanu Slide is seen near the center top in this bathymetry image of the Hawaiian archipelago,

Nuʻuanu Slide or Nuʻuanu Debris Avalanche is the largest of seventeen known submarine landslides around the Hawaiian Islands and at 200 kilometers (124 mi) in length, one of the largest landslides on Earth. It broke from the eastern or windward side of Oʻahu, Hawaiʻi between 1 and 1.5 million years ago and lies in the Pacific Ocean north of Molokaʻi.[1][2]

At the time of collapse, Oʻahu was part of the conglomerate island Maui Nui, elevated above the ocean from lower sea levels, and contained the Koʻolau Volcano. The eastern half of the mountain collapsed nearly in half at the caldera. The remains of the eastern half of the caldera is now Kāneʻohe Bay and the new western side is the Koʻolau Range above the bay, including observation point Nuʻuanu Pali. Though the remaining ridge appears to be a steep and weathered fault scarp, evidence suggests the geographic features are from wind and water rather than the landslide event.[2]

The volcano collapsed nearly in half at the caldera with the eastern half falling into the ocean cataclysmically with enough force to send debris, part of which forms the massive Tuscaloosa Seamount, across the ocean floor and up a ridge.[2] This landslide created a massive tsunami which ravaged the islands and possibly the Western coast of ancient North America. [3]

References

[edit]
  1. ^ "Bathymetry image of the Hawaiian archipelago". United States Geological Survey (USGS).
  2. ^ a b c Dunn, Patrick D. (2009). Vanished Islands and Hidden Continents of the Pacific. University of Hawai'i Press. pp. 44–46. ISBN 978-0-8248-3219-3 – via Project MUSE.
  3. ^ Satake, Kenji; Smith, John R.; Shinozaki, Ken (2002). "Three-dimensional reconstruction and Tsunami model of the Nuuanu and Wailau giant landslides, Hawaii". Hawaiian Volcanoes: Deep Underwater Perspectives. Geophysical Monograph Series. Vol. 128. pp. 333–346. doi:10.1029/GM128p0333. ISBN 0-87590-987-6 – via ResearchGate.
[edit]