 | |  |
|
| Enlarge ImageThe new X-ray fluorescence core scanner simultaneously captures digital photographs and X-ray images of a core sample while detecting the presence of any of 80 chemical elements—-in a matter of hours and without breaking the core's surface. (Photo by Tom Kleindinst) |
|
|  |
|
| Enlarge ImageGeologist Liviu Giosan examines the data output from the new X-ray fluorescence (XRF) core scanner (behind him) at Woods Hole Oceanographic Institution. The XRF was built by Cox Analytical Systems of Sweden and purchased by WHOI with funding from the Major Research Instrumentation grant program of the National Science Foundation. It is the first and only XRF core scanner in the United States, and just one of five similar devices in the world. (Photo by Tom Kleindinst, WHOI) |
|
|  |
|
| Enlarge ImageJessica Tierney, a WHOI research assistant, aligns a sediment core for examination in the XRF scanner. Tierney needed three months in the lab to develop a profile of a core from Peru that she was studying; with the XRF, she was able to collect the same data—plus X-ray images—in three days. (Photo by Tom Kleindinst, WHOI) |
|
|  |
|
| Enlarge ImageAn XRF scan of a sediment core from the Cariaco Basin (off Venezuela) combines observations from all three instrument sensors. The X-ray image (gray and black) reveals sedimentary layers that are not otherwise visible in a standard photograph (brown). The concentration of titanium, overlaid in yellow, indicates past fluctuations in atmospheric moisture and dust in the region. (Courtesy of Liviu Giosan, WHOI) |
|
|  |
|
| Enlarge ImageTo study core samples the traditional way, scientists must cut them down the middle and meticulously dissect them. It is a time- and labor-intensive process that gradually destroys unique—and not easily replaceable—cores. (Photo by Tom Kleindinst, WHOI) |
|
|
Related Links |
|
|
Fans of the Star Trek science fiction series will
remember the “tricorder,” an all-purpose sensor that Kirk, Spock, and McCoy
waved over objects, from rocks and spaceships to alien life forms, to determine
what they were made of.
“We now have our own version of the tricorder,” said Liviu
Giosan, a coastal geologist who was instrumental in acquiring and setting up an
X-ray fluorescence (XRF) core scanner at Woods Hole Oceanographic Institution.
It is the first of its kind in the United States.
Like the tricorder (and some instruments on NASA’s Mars
rovers), the XRF reveals intimate details of the composition of ancient mud and
rock, which can contain a variety of clues about past climate and environmental
conditions on Earth. The $450,000 instrument simultaneously captures digital
photographs and X-ray images of samples, while detecting measurable amounts of
any of 80 chemical elements from aluminum (atomic number 11) to uranium (atomic
number 92) without breaking the surface of the core. It gathers all of this
data in a matter of hours.
Time is money...and better science
Traditionally, scientists (or more likely, their students)
spend months to years sifting through mud and sediment cores to measure carbon,
trace metals, pollen, microscopic shells, and other materials that accumulate
over time in coastal marshes and dunes or on the seafloor. By analyzing the
sequential layers of this preserved detritus, scientists can reconstruct past
changes in ocean temperatures, rainfall, wind, and vegetation patterns. They
can determine when droughts, hurricanes, or blooms of marine plankton occurred.
To study core samples, scientists must cut them down the
middle and meticulously dissect them. It is a time- and labor-intensive process
that gradually destroys unique—and not easily replaceable—cores. Sometimes
cores must be shipped to other locations (in WHOI’s case, a local hospital) if
scientists need an X-ray view to see layers undetected by the eye.
With the XRF scanner, researchers place a core into a
motorized, computer-controlled carriage that slides the sediments past a camera
and X-ray source. A charge-coupled device captures high-resolution images a
millimeter at a time. A sequential pair of X-ray beams is then fired into the
core: One creates an X-ray image; the other stimulates the atoms in the sample,
causing energy to be emitted in the form of electromagnetic radiation
(fluorescent light). Each element releases radiation with a distinctive wavelength
that can be detected by the XRF.
It does all this without taking a single bit of the core,
meaning that other scientists can virtually dig into the same mud and pursue
other chemical clues locked inside.
“We now have the ability to generate high-quality,
high-resolution geochemical records very quickly,” said Konrad Hughen, a WHOI
geochemist who has been reconstructing ancient climate from sediments collected
near Peru, Chile, and Venezuela. “The XRF is incredibly efficient and
incredibly precise, and it will completely revolutionize how we do our work.”
Diversifying scientific assets
MIT/WHOI Joint Program student Jon Woodruff and geologist
Jeff Donnelly have already used the new tool to expand their studies of ancient
hurricanes. The sensitivity of the machine allows them to see evidence of
ancient storms and climate shifts that they could not detect before—and some
that they would not have looked for. The speed of XRF analysis gives them the
ability to examine and compare cores from many different continents in the time
it formerly took to analyze just one spot on the globe.
“The XRF is my favorite new toy,” said Donnelly. “It has
fundamentally changed the experience of studying sediments. We can ask bigger
and broader questions.”
The XRF also allows what may be the biggest leap forward in
sediment science: the ability to quickly analyze many different environmental
markers at the same time. Information about individual elements can be
valuable, but scientists can learn more—and be more confident in their
analyses—when they combine and compare multiple records.
For example, Hughen and others had found through previous
analyses that aluminum and titanium concentrations both decreased sharply in
sediments from the Cariaco Basin (off Venezuela) during a period of abrupt
climate change about 11,600 years ago (known as the “Younger Dryas”). The
decreases suggested that the period was drier, with less rain causing less
material to run off from land into the ocean.
But with the XRF, Hughen simultaneously measured the
concentrations of each element, giving a precise ratio of one to the other.
Those ratios indicated a surge of particles from African deserts blowing into
the ocean off Venezuela—corroborating, but different, evidence of a drier climate
during the Younger Dryas.
Sharing the wealth
The arrival of the XRF in Woods Hole opens doors for the
entire oceanographic community. Giosan and Donnelly are
figuring out how to share their oceanographic “tricorder” with the rest of the
research world.
“Liviu took the initiative and made the case for the
instrument, invested a lot of his own valuable research time, and then was
open-minded enough to let others try things out,” said Lex van Geen, a chemist
at the Lamont-Doherty Earth Observatory and a 1990 graduate of the MIT/WHOI
Joint Program. Van Geen contacted Giosan to see if the XRF could detect trace
metals in sediments he extracted from the Pacific coast of Mexico as part of an
effort to reconstruct past ocean temperatures and oceanic life.
“It’s
a credit to WHOI and the National Science Foundation for providing the support
to make this possible,” van Geen said. “Access to the XRF could have been much more
constricted, but there is no sense of a monopoly on this instrument.”
— Mike Carlowicz
Posted: February 28, 2006 [top] |
