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| Summer student Ryan Pike (NRCan) is getting ready to deploy the
sonobuoy at the stern of the Louis. A radio transmitter will relay the data
back to the ship.
Photo by Thomas Funck, GEUS. |
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| Senior scientist Thomas Funck (GEUS) in the compressor container.
The compressed air (pressure of 2000 pounds per square inch) is used by the
air guns to create the sound waves for the seismic experiment. Photo by Ryan Pike. |
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| Technician Borden Chapman (NRCan) with his summer student Ryan
Pike in the seismic laboratory. This is the control centre for firing the
air guns and recording the data from the hydrophones that listen to the
sound waves. Photo by Rick Krishfield, WHOI. |
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| Air bubbles rising to the surface from an airgun shot. Photo by Rick Krishfield, WHOI. |
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Cruise - 2006 Dispatches
Calendar
Dispatch 24, August 28, 2006
By Thomas Funck, Geological Survey of Denmark and Greenland, GEUS
Sonobuoys
Today was a big day for the seismic group onboard the Louis. We had a
twelve-hour interval to map the sediment thickness and water depth in the
western Canada Basin. This work is related to the United Nations Convention
on the Law of the Sea that allows coastal states to extend their
jurisdiction beyond the present 200 nautical mile limit into a zone that is
called the "extended continental shelf" (see also Dispatch 6). However, the
UN requires the coastal states to map the extended continental shelf to
provide documentation on the sediment thickness and the water depth. The UN
has very specific rules how far a state can extend its shelf, but the
thicker the sediments the bigger the potential claim.
Today we had the chance to test our new equipment over a longer time period
and to collect seismic data in an area of Canada Basin where we expect thick
sediments. Shortly after breakfast, our seismic sound source was lowered
into the water by the deck crew. The source consists of so called air guns.
Once a minute we release 1500 cubic inch of compressed air into the water.
The pressure of the air is 2000 psi (pounds per square inch), which is 60
times higher than in a regular car tire. The sound propagates to the
seafloor and farther below into the sediments. Whenever the sound wave hits
a new sediment layer, the sound will be reflected back to the surface, where
we are listening with a hydrophone (a kind of very sensitive microphone).
In the lab, we do a first quality control on a paper record, which looks
similar to an echo sounder. We can see the seafloor and all the different
sediment layers below, which could consist for example of mud, clay or sand.
Later I take the digital data to my computer and do "magic" things (seismic
data processing), which enhance the image of the subsurface.
With our airgun and hydrophone we can only measure the time it takes for the
sound to travel from the airguns, down to a sediment layer and back to the
surface. To determine the sediment thickness we also need to know the
velocity with which the sound propagates through the sediments. To do that,
our technician Borden Chapman (NRCan) and his summer student (Ryan Pike)
deployed a sonobuoy this morning. The sonobuoy is equipped with a hydrophone
and a radio transmitter. Back on the ship we receive the radio signal and
that way we can listen to our airgun shots as the ship moves away from the
buoy. A modeling program in the computer can then calculate the velocity of
sound within the various sediment layers.
With all that information we can calculate the sediment thickness and use it
for Canada's submission to the UN to extend the continental shelf. Everybody
onboard is pretty excited about the prospect of making Canada bigger. At the
same time, we also get a lot of data that can give us information on the
geology of the Arctic and how the 3800-m deep Canada Basin developed over
the last 130 million years.
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