Have you ever thought to use a clock to identify mineral deposits or concealed water resources within the Earth? An international team headed by astrophysicists Philippe Jetzer and Ruxandra Bondarescu from the University of Zurich is convinced that ultraprecise portable atomic clocks will make this a reality in the next decade. The scientists argue that these atomic clocks have already reached the necessary degree of precision to be useful for geophysical surveying. They say that such clocks will provide the most direct measurement of the geoid – the Earth's true physical form. It will also be possible to combine atomic clocks measurements to existent geophysical methods to explore the interior of the Earth.
Determining geoid from general relativity
Today, the Earth's geoid – the surface of constant gravitational potential that extends the mean sea level – can only be determined indirectly. On continents, the geoid can be calculated by tracking the altitude of satellites in orbit. Picking the right surface is a complicated, multivalued problem. The spatial resolution of the geoid computed this way is low – approximately 100 km.
Using atomic clocks to determine the geoid is an idea based on general relativity that has been discussed for the past 30 years. Clocks located at different distances from a heavy body like our Earth tick at different rates. Similarly, the closer a clock is to a heavy underground structure the slower it ticks – a clock positioned over an iron ore will tick slower than one that sits above an empty cave. "In 2010 ultraprecise atomic clocks have measured the time difference between two clocks, one positioned 33 centimeters above the other," explains Bondarescu before adding: "Local mapping of the geoid to an equivalent height of 1 centimeter with atomic clocks seems ambitions, but within the reach of atomic clock technology."
Geophysical surveying with atomic clocks
According to Bondarescu, if an atomic clock is placed at sea level, i.e., at the exact altitude of the geoid, a second clock could be positioned anywhere on the continent as long as it is synchronized with the first clock. The connection between the clocks can be made with fiber optics cable or via telecommunication satellite provided that the transmission is reliable enough. The second clock will tick faster or slower, depending on whether it is above of beneath the geoid. The local measurement of the geoid can then be combined with other geophysical measurements such as those from gravimeters, which measure the acceleration of the gravitational field, to get a better idea of the underground structure.
Mappings possible to great depths
In principle, atomic clock surveying is possible to great depth provided that the heavy underground structure to be studied is large enough to affect the tick rates of clocks in a measurable manner. The smallest structure that atomic clocks accurate to 1 centimeter in geoid height can determine is a buried sphere with a radius of about 1.5 kilometer buried at 2 kilometers under the surface provided it has a density contrast of about 20% with the surrounding upper crust. However, scientists estimate that the same clocks would be sensitive to a buried sphere with a radius of 4 kilometers at a depth of about 30 kilometers for the same density contrast.
Currently, ultraprecise atomic clocks only work in labs. In other words, they are not transportable and thus cannot be used for measurements in the field. However, this is all set to change in the next few years: Various companies and research institutes, including the Centre Suisse d'Electronique et de Microtechnique CSEM based in Neuchâtel, are already working on the development of portable ultraprecise atomic clocks. "By 2022 at the earliest, one such ultraprecise portable atomic clock will fly into Space on board an ESA satellite," says Professor Philippe Jetzer, the Swiss delegate for the STE-Quest satellite mission aimed at testing the general relativity theory very precisely. As early as 2014 or 2015, the "Atomic Clock Ensemble in Space ACES" is to be taken to the International Space Station ISS. ACES is an initial prototype that does not yet have the precision of STE-QUEST.
Ruxandra Bondarescu, Mihai Bondarescu, György Hetényi, Lapo Boschi, Philippe Jetzer, Jayashree Balakrishna. Geophysical applicability of atomic clocks: direct continental geoid mapping. Geophysical Journal International. August 24, 2012. DOI: 10.1111/j.1365-246X.2012.05636.x
University of Zurich: http://www.uzh.ch
This press release was posted to serve as a topic for discussion. Please comment below. We try our best to only post press releases that are associated with peer reviewed scientific literature. Critical discussions of the research are appreciated. If you need help finding a link to the original article, please contact us on twitter or via e-mail.
A playfully named subatomic particle is confirmed, and beats rivals Bert and Ernie in terms of energy. Next step: to find a cluster of space neutrinos
Can matter be made of four quarks bound together? The discovery of a new particle has been confirmed at the LHC and may be our best hope of an answer
Traditional spice producers and synthetic biologists don't have to compete – there's room for both
Cortines School's Greg Schiller was removed by L.A. Unified after two students' projects were deemed to resemble weapons. A popular Los Angeles high school science teacher has been suspended after students turned in projects that appeared dangerous to administrators, spurring a campaign calling for his return to the classroom.
Eighty percent of the universe is utterly invisible, but an exotic dance of mutually annihilating particles may explain it all
NASA says the Western Pacific island of Nishino-shima has merged with its newly created volcanic companion, forming one larger landmass.
Scientist Lawrence Krauss says clips of him were "mined" to lend credibility to The Principle, a film he describes as "stupid" and "unbelievable."
An experiment located at the bottom of a US gold mine could offer the best chance yet of detecting dark matter, scientists believe.
The U.S. Navy is planning sea trials for a weapon that can fire a low-cost, 23-pound (10-kg) projectile at seven times the speed of sound using electromagnetic energy, a "Star Wars" technology that will make enemies think twice, the Navy's research chief said.
A spectacular satellite view of China's Piqiang fault shows 50 million years of Earth's history torn asunder