[meteorite-list] Waves Generated by Russian Meteor Recorded in U.S.

From: Ron Baalke <baalke_at_meteoritecentral.com>
Date: Thu, 7 Mar 2013 16:16:22 -0800 (PST)
Message-ID: <201303080016.r280GMQ9028448_at_zagami.jpl.nasa.gov>

http://www.rdmag.com/news/2013/03/waves-generated-russian-meteor-recorded-us

Waves generated by Russian meteor recorded in U.S.
National Science Foundation
March 7, 2013

A network of seismographic stations recorded spectacular signals
from the blast waves of the meteor that landed near Chelyabinsk, Russia,
as the waves crossed the United States.

The National Science Foundation- (NSF) supported stations are used to
study earthquakes and the Earth's deep interior.

While thousands of earthquakes around the globe are recorded by seismometers
in these stations - part of the permanent Global Seismographic Network (GSN)
and EarthScope's temporary Transportable Array (TA) - signals from large
meteor impacts are far less common.

The meteor explosion near Chelyabinsk on Feb. 15, 2013, generated ground
motions and air pressure waves in the atmosphere. The stations picked up
the signals with seismometers and air pressure sensors.

The ground motions were recorded by the GSN and the TA. The pressure waves
were detected by special sensors that are part of the TA.

"The NSF-supported Global Seismic Network and EarthScope Transportable Array
made spectacular recordings of the Chelyabinsk meteor's impact," says Greg
Anderson, program director in NSF's Division of Earth Sciences.

"These recordings of seismic waves through the Earth, and sound waves
through the atmosphere, are good examples of how these facilities can help
global organizations better monitor earthquakes, clandestine nuclear tests
and other threats."

Incoming! Then outgoing!

The Chelyabinsk meteor exploded in the atmosphere at approximately 9.20 a.m.
local time. The blast caused significant damage in the city, breaking
thousands of windows and injuring more than 1,000 people.

Energy from the blast created pressure waves in the atmosphere that moved
rapidly outward and around the globe. The blast also spread within the Earth
as a seismic wave.

The two wave types - seismic wave and pressure wave - travel at very different
speeds.


Waves in the ground travel quickly, at about 3.4 kilometers per second. Waves
in the atmosphere are much slower, moving at about 0.3 kilometers per
second, and can travel great distances.

GSN stations in Russia and Kazakhstan show the ground-traveling wave as a
strong, abrupt pulse with a duration of about 30 seconds.

The atmospheric waves--referred to as infrasound--were detected across a range
of inaudible frequencies and were observed at great distances on infrasound
microphones.

When the infrasound waves reached the eastern United States - after traveling
8.5 hours through the atmosphere across the Arctic from the impact site in
Russia - they were recorded at TA stations at the Canadian border.

The infrasound waves reached Florida three hours later, nearly 12 hours after
the blast. Infrasound sensors at TA stations along the Pacific coast and in
Alaska also recorded the blast, but with signatures that were shorter and
simpler than those recorded by stations in the mid-continent and along the
southeastern seaboard.

The duration of the signals, and the differences between the waveforms in
the east and west, scientists believe, are related to the way in which
energy travels and bounces on its long path through the atmosphere.

EarthScope Transportable Array

The Transportable Array is operated by the IRIS (Incorporated
Research Institutions for Seismology) Consortium as part of NSF's EarthScope
Project. It consists of 400 stations traversing the United States, recording
at each site along the way for two years.

Each of the TA stations was originally equipped with sensitive broadband
seismometers for measuring ground motions, but in 2010, NSF awarded the
University of California, San Diego, in cooperation with IRIS, funding to
add pressure and infrasound sensors.

These special sensors help scientists understand how changes in pressure
affect ground motions recorded by the TA's seismometers and provide a view of
regional pressure changes related to weather patterns.

The sensors also record events such as tornadoes, derechos, rocket launches,
chemical explosions--and meteor impacts.

The Chelyabinsk meteor is the largest signal recorded to date.

In 2013, the Transportable Array will reach states in the Northeast, completing
its traverse of the contiguous United States and southern Canada.

Global Seismographic Network

The GSN's primary mission is collecting data to monitor worldwide earthquakes
and to study the Earth's deep interior.

It's funded jointly by NSF and the U.S. Geological Survey and is managed and
operated by IRIS in collaboration with the U.S. Geological Survey's Albuquerque
Seismological Laboratory and the University of California, San Diego.

As part of a worldwide network of seismic stations, data from the GSN have
contributed over the past three decades to the monitoring of nuclear explosions
at test sites in the United States, the former Soviet Union, India, Pakistan
and Korea. For example, GSN stations provided observations of the Korean
nuclear test on Feb. 12, 2013.

Source: National Science Foundation
Received on Thu 07 Mar 2013 07:16:22 PM PST


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