Selasa, 01 Februari 2011

Earthquake Ground Deformation

Remote sensing and GPS studies of the Magnitude 7.2 El Mayor-Cucapha Earthquake

Republished from a December, 2010 press release by NASA.

Earthquake Ground Deformation Data

New technologies developed by NASA and other agencies are revealing surprising insights into a major earthquake that rocked parts of the American Southwest and Mexico in April, 2010 including increased potential for more large earthquakes in Southern California.

At the fall, 2010 meeting of the American Geophysical Union in San Francisco, scientists from NASA and other agencies presented the latest research on the magnitude 7.2 El Mayor-Cucapah earthquake, that region's largest in nearly 120 years. Scientists have studied the earthquake's effects in unprecedented detail using data from GPS, advanced simulation tools and new remote sensing and image analysis techniques, including airborne light detection and ranging (LiDAR), satellite synthetic aperture radar and NASA's airborne Uninhabited Aerial Vehicle Synthetic Aperture Radar (UAVSAR).

Siginificant Findings:

  • The earthquake is among the most complex ever documented along the Pacific/North American tectonic plate boundary. The main shock activated segments of at least six faults, some unnamed or previously unrecognized. It triggered slip along faults north of the border as far as 165 kilometers (about 100 miles) away, including the San Andreas, San Jacinto, Imperial and Superstition Hills Faults, and many faults in California's Yuha Desert, some not previously mapped. Some of this slip was quiet, without detectable earthquakes. Activity was observed on several northwest-trending faults due for potentially large earthquakes.
  • The rupture's northern end in Southern California resembles the frayed end of a rope. The complex, 32-kilometer (20-mile) network of faults that slipped there during and after the earthquake -- many unnamed or previously unrecognized -- reveals how the earthquake distributed strain.
  • Satellite radar, UAVSAR and GPS station data show additional slip along some of the Yuha Desert faults in the months after the main earthquake. Recent data from UAVSAR and satellite radar show this slip slowed and probably stopped in late summer or early fall.
  • Mexico's Sierra Cucapah mountains were, surprisingly, lowered, not raised, by the earthquake.
  • The main rupture jumped an 11-kilometer (7-mile) fault gap-more than twice that ever observed before.
  • UAVSAR and satellite radar reveal deep faulting that may be a buried continuation of Mexico's Laguna Salada Fault that largely fills the gap to California's Elsinore Fault. This could mean the fault system is capable of larger earthquakes. A connection had only been inferred before.
  • Analyses show a northward advance of strain after the main shock, including a pattern of triggered fault slip and increased seismicity. The July 7, 2010 magnitude 5.4 Collins Valley earthquake on the San Jacinto Fault may have been triggered by the main earthquake.
  • Forecasting methods in development suggest earthquakes triggered by the main shock changed hazard patterns, while experimental virtual reality scenarios show a substantial chance of a damaging earthquake north of Baja within three  to 30 years of a Baja quake like the one in April. 

Plate Tectonics and the Hawaiian Hot Spot

Origin of the Hawaiian Islands

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The Hawaiian Islands are the tops of gigantic volcanic mountains formed by countless eruptions of fluid lava over several million years; some tower more than 30,000 feet above the seafloor. These volcanic peaks rising above the ocean surface represent only the tiny, visible part of an immense submarine ridge, the Hawaiian Ridge—Emperor Seamount Chain, composed of more than 80 large volcanoes.

This range stretches across the Pacific Ocean floor from the Hawaiian Islands to the Aleutian Trench. The length of the Hawaiian Ridge segment alone, between the Island of Hawai'i and Midway Island to the northwest, is about 1,600 miles, roughly the distance from Washington, D.C., to Denver, Colorado. The amount of lava erupted to form this huge ridge, about 186,000 cubic miles, is more than enough to cover the State of California with a layer 1 mile thick.


Plate Tectonics and the Hawaiian Hot Spot

In the early 1960s, the related concepts of "seafloor spreading" and "plate tectonics" emerged as powerful new hypotheses that geologists used to interpret the features and movements of the Earth's surface layer. According to the plate tectonic theory, the Earth's rigid outer layer, or "lithosphere," consists of about a dozen slabs or plates, each averaging 50 to 100 miles thick. These plates move relative to one another at average speeds of a few inches per year—about as fast as human fingernails grow. Scientists recognize three common types of boundaries between these moving plates.




(1) Divergent Boundaries

Adjacent plates pull apart, such as at the Mid-Atlantic Ridge, which separates the North and South America Pates from the Eurasia and Africa Plates. This pulling apart causes "seafloor spreading" as new material from the underlying less rigid layer, or "asthenosphere," fills the cracks and adds to these oceanic plates.

(2) Convergent Boundaries

Two plates move towards one another and one is dragged down (or "subducted") beneath the other. Convergent plate boundaries are also called "subduction zones" and are typified by the Aleutian Trench, where the Pacific Plate is being subducted under the North America Plate. Mount St. Helens (southwest Washington) and Mount Fui (Japan) are excellent examples of subduction-zone volcanoes formed along convergent plate boundaries.

(3) Transform Boundaries

One plate slides horizontally past another. The best-known example is the earthquake-prone San Andreas Fault Zone of California, which marks the boundary between the Pacific and North America Plates.






Earthquakes and Volcanoes on Plate Boundaries

Nearly all of the world's earthquakes and active volcanoes occur along or near the boundaries of the Earth's shifting plates. Why then are the Hawaiian volcanoes located in the middle of the Pacific Plate, more than 2,000 miles from the nearest boundary with any other tectonic plate? The proponents of plate tectonics at first had no explanation for the occurrence of volcanoes within plate interiors ("intraplate" volcanism).

The "Hot Spot" Hypothesis

Then in 1963, J. Tuzo Wilson, a Canadian geophysicist, provided an ingenious explanation within the framework of plate tectonics by proposing the "hot spot" hypothesis. Wilson's hypothesis has come to be accepted widely, because it agrees well with much of the scientific data on linear volcanic island chains in the Pacific Ocean in general—and the Hawaiian Islands in particular.

How Deep Are Hot Spots?

According to Wilson, the distinctive linear shape of the Hawaiian-Emperor Chain reflects the progressive movement of the Pacific Plate over a "deep" and "fixed" hot spot. In recent years, scientists have been debating about the actual depth(s) of the Hawaiian and other Earth hot spots. Do they extend only a few hundred miles beneath the lithosphere? Or do they extend down thousands of miles, perhaps to Earth's core-mantle boundary?

Do Hot Spots Move?

Also, while scientists general agree that hot spots are fixed in position relative to the faster moving overriding plates, some recent studies have shown that hot spots can migrate slowly over geologic time. In any case, the Hawaiian hot spot partly melts the region just below the overriding Pacific Plate, producing small, isolated blobs of molten rock (magma). Less dense than the surrounding solid rock, the magma blobs come together and rise buoyantly through structurally weak zones and ultimately erupt as lava onto the ocean floor to build volcanoes.

The Hawaiian-Emperor Chain

Over a span of about 70 million years, the combined processes of magma formation, eruption, and continuous movement of the Pacific Plate over the stationary hot spot have left the trail of volcanoes across the ocean floor that we now call the Hawaiian-Emperor Chain. A sharp bend in the chain about 2,200 miles northwest of the Island of Hawai'i was previously interpreted as a major change in the direction of plate motion around 43–45 million years ago (Ma), as suggested by the ages of the volcanoes bracketing the bend.

However, recent studies suggest that the northern segment (Emperor Chain) formed as the hot spot moved southward until about 45 Ma, when it became fixed. Thereafter, northwesterly plate movement prevailed, resulting in the formation of the Hawaiian Ridge "downstream" from the hotspot.

Age of the Islands

The Island of Hawai'i is the southeasternmost and youngest island in the chain. The southeasternmost part of the Island of Hawai'i presently overlies the hot spot and still taps the magma source to feed its active volcanoes. The active submarine volcano Lö'ihi, off the Island of Hawai'i's south coast, may mark the beginning of the zone of magma formation at the southeastern edge of the hot spot. With the possible exception of Maui, the other Hawaiian islands have moved northwestward beyond the hot spot—they were successively cut off from the sustaining magma source and are no longer volcanically active.

The progressive northwesterly drift of the islands from their point of origin over the hot spot is well shown by the ages of the principal lava flows on the various Hawaiian Islands from northwest (oldest) to southeast (youngest), given in millions of years: Ni'ihau and Kaua'i, 5.6 to 3.8; O'ahu, 3.4 to 2.2; Moloka'i, 1.8 to 1.3; Maui, 1.3 to 0.8; and Hawai'i, less than 0.7 and still growing.

Even for the Island of Hawai'i alone, the relative ages of its five volcanoes are compatible with the hot-spot theory (see map, page 3). Kohala, at the northwestern corner of the island, is the oldest, having ceased eruptive activity about 120,000 years ago. The second oldest is Mauna Kea, which last erupted about 4,000 years ago; next is Hualälai, which has had only one eruption (1800–1801) in written history. Lastly, both Mauna Loa and Kïlauea have been vigorously and repeatedly active in the past two centuries. Because it is growing on the southeastern flank of Mauna Loa, Kïlauea is believed to be younger than its huge neighbor.

The size of the Hawaiian hot spot is not well known, but it presumably is large enough to encompass and feed the currently active volcanoes of Mauna Loa, Kïlauea, Lö'ihi and, possibly, also Hualälai and Haleakalä. Some scientists have estimated the Hawaiian hot spot to be about 200 miles across, with much narrower vertical passageways that feed magma to the individual volcanoes.

What is Geology? - What Does a Geologist Do?

Definition of Geology:

Geology is the study of the Earth, the materials of which it is made, the structure of those materials, and the processes acting upon them. It includes the study of organisms that have inhabited our planet. An important part of geology is the study of how Earth’s materials, structures, processes and organisms have changed over time.

What Does a Geologist Do?

Geologists work to understand the history of our planet. The better they can understand Earth’s history the better they can foresee how events and processes of the past might influence the future. Here are some examples:
Geologists study earth processes:   Many processes such as landslides, earthquakes, floods and volcanic eruptions can be hazardous to people. Geologists work to understand these processes well enough to avoid building important structures where they might be damaged. If geologists can prepare maps of areas that have flooded in the past they can prepare maps of areas that might be flooded in the future. These maps can be used to guide the development of communities and determine where flood protection or flood insurance is needed.

Geologists study earth materials:   People use earth materials every day. They use oil that is produced from wells, metals that are produced from mines, and water that has been drawn from streams or from underground. Geologists conduct studies that locate rocks that contain important metals, plan the mines that produce them and the methods used to remove the metals from the rocks. They do similar work to locate and produce oil, natural gas and ground water.

Geologists study earth history:   Today we are concerned about climate change. Many geologists are working to learn about the past climates of earth and how they have changed across time. This historical geology news information is valuable to understand how our current climate is changing and what the results might be.