Piston Coring

Today piston coring is one of the more common sea floor sampling methods. The piston corer was invented in 1947 by Professor Borje Kullenberg to enable the Swedish Deep Sea Expedition to collect long samples of sediment, up to 24 meters long, from beneath the sea floor. This tool acquires samples that are virtually undisturbed, making this tool and modified versions of it a staple in modern sea floor sampling.


Let's take look at the tool and its core sample, and see how it all works.


Piston Corer.
(Photo used by permission, Dr. Mark L. Holmes, Univ. of Washington)


The piston coring tool is winched over the side of the research ship just prior to a sampling run. Notice the long coring tube where the sea floor sediment will be collected, the weight located on top of the tube and the trip arm extending to the left above the weight.


Modified Kullenberg piston corer.
(Credit: US Coast Guard)


Panel 1 - The piston corer appears much as it did in the previous photo, but it is now approaching the sea floor. Notice the parts of the tool, the piston corer, the piston at the tip, and the weight, tripping arm, loops of trawl wire and gravity corer. The entire assembly is connected by wire to the winch on the ship.

Panel 2 - The gravity corer has just touched the sea floor. This triggers the release of the piston corer and it drops to the seafloor. The weight helps the corer impact the sea floor.

Panel 3 - The trawl wire is fully extended stopping the piston inside the core tube, however the core tube continues to penetrate the sea bottom. The vacuum suction created by the stopped piston and moving tube allows the sediment sample to enter the tube comparatively undisturbed. As soon as the sample is inside the core tube, the entire assembly is winched back on board the ship.


Piston core removed from corer.
(Credit: U.S. Geological Survey, US Department of the Interior Eddy Lee,
Texas A&M University, aboard the R/V Gyre)


Once the assembly is back on board, the piston core sample is removed from the corer and cut into more manageable lengths. These small core segments are later cut in half lengthwise so the sample can be examined and subsampled.


Split piston core being subsampled.
(Credit: U.S. Geological Survey, US Department of the Interior Hans Nelson and Gita Dunhill,
USGS - Menlo Park, aboard the R/V Gyre)


The cut and split core sections are described and subsampled for detailed analysis that often includes foram age and environment analysis.


(source : http://oceanworld.tamu.edu/students/forams/forams_piston_coring.htm)



What is it and why do we use it?

The piston corer is a long, heavy tube plunged into the seafloor to extract samples of mud sediment. A piston inside the tube allows scientists to capture the longest possible samples, up to 90 feet in length. They are simple and elegant in design; in 1947, scientist Maurice Ewing said that a piston corer "brings up samples of the ocean floor just as a housewife cores an apple."


How is the piston corer different from other corers?

The goal of all corers is to extract samples of mud. Ewing once referred to corers as cookie cutters. The length and diameter of the mud cookies they extract depends on the type of corer used. Traditional corers are quite simple in design: a long tube surmounted by a ton or so of lead. In the late 1940s, the Swedish oceanographer Börje Kullenberg made modifications on this design, adding an internal piston that helps researchers gather even longer mud samples. Piston corers, like their cousin the gravity corer, are generally used in areas with soft sediment, such as clay. A gravity corer is just a weighted pipe that is allowed to free fall into the water. Piston corers have a piston mechanism that is triggered when the corer hits the bottom. The piston helps to avoid disturbing the sediment.


What enables a corer to capture a sediment sample?

If you have ever poked a straw into a milkshake, put your finger over the top of the straw, then extracted the straw with the ice cream trapped inside, you have an idea of how the piston corer works. Like the straw, the corer plunges into the seafloor and collects mud in its hollow open pipe. A seal on the bottom of the device will retain the sediment sample during retrieval.


What are the advantages of using a piston corer?

Simply making a gravity corer longer does not insure the recovery of a longer sample. The addition of the internal piston allows the soft sediment to be captured without significant compression or disturbance. This allows researchers to capture the best possible sediment sample.


What are the disadvantages of using a piston corer?

They are heavy, long, and sometimes difficult to handle. Because of the operations involved and equipment needed, piston corers cannot be executed from every research vessel. Special handling equipment is required to safely launch and recover a deep sea piston coring system.


Why are cores from the ocean special?

Cores extracted from the sea are especially useful because, unlike land sediments, they are largely undisturbed; no people have dug around them, or walked on top of them. By minimizing disturbance, scientists are able to see the clearest picture of specific time periods on Earth.


Why study sediment?

By studying sediment, scientists can learn about ocean circulation, climate, the formation of ore deposits, the movement of oceanic plates, salinity of water, and the stability of the seafloor for oil drilling and exploration. Sediment cores allow scientists to see the presence or absence of specific fossils that may indicate climate patterns at times in the past, such as during the ice ages. Some scientists refer to the cores as time capsules, because the information they contain can span the past hundreds of thousands and even millions of years. Scientists may then use this information to improve understanding of the climate system and predict patterns and events in the future.


Sources

Jim Broda, research specialist in the Geology and Geophysics Department at WHOI

Lamont-Doherty Earth Observatory of Columbia University: Twelve Perspectives on the First 50 Years, 1949-1999

Woods Hole Oceanographic Institution Exhibit Center, coring exhibit (text by Stephanie Murphy)


(source: http://www.whoi.edu/instruments/viewInstrument.do?id=8087)


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Awalnya Saya sedang menempuh bangku kuliah di Fakultas Perikanan dan Ilmu Kelautan Universitas Padjadjaran, Program Studi Ilmu Kelautan, Alhamdulillah sekarang Saya sudah LULUS. Saya menempuh bangku perkuliah sejak tahun 2007 sampai dengan Mei 2011. Tertarik pada pengembangan potensi kelautan nasional dan berbagai masalah kelautan yang di hadapi bangsa Indonesia. Ini catatan perjalan Saya, pemikiran yang ditulis dan dituangkan mudah-mudahan menginspirasi pembacanya. Salam hangat. Ogys

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