Results from the first run of the Large Underground Xenon (LUX) experiment operating a mile underground in the Black Hills of South Dakota, have proven the detector's sensitivity and ruled out some possible candidates for a dark matter particle.
Initial results from 85 days worth of accumulated data were announced today, Oct. 30 at a seminar today at the Sanford Underground Research Facility in Lead, S.D.
"LUX is already producing the world's best results and excluding parameter space for a dark matter particle," said Matthew Szydagis, a postdoctoral researcher at the University of California, Davis Department of Physics. Szydagis is responsible for coordinating data analysis among the members of the LUX team.
Mani Tripathi, professor of physics at UC Davis, is one of the seven founding principal investigators who proposed the LUX experiment in 2006. "We are finally seeing the fruits of our labor after these many years," he said.
Dark matter is the most abundant form of matter in the universe but has so far been inferred only by its gravitational effects on light from distant galaxies and clusters of galaxies. The leading theoretical candidates for a dark matter particle are WIMPs, or Weakly Interacting Massive Particles – so-called because they are postulated to interact ever so feebly with ordinary matter.
LUX was designed to have greater sensitivity to detect WIMPs than any other existing experiment. Recently, other researchers using ultra-cold silicon detectors reported three candidate WIMP events. However, these WIMPs would have produced more than 1,600 events in LUX's much larger detector, or one every 80 minutes in the recent run. No such signals were seen.
"This is only the beginning for LUX," said Dan McKinsey, a physicist at Yale University and co-spokesperson for the project. "Now that we understand the instrument and its backgrounds, we will continue to take data, testing for more and more elusive candidates for dark matter."
In both theory and practice, collisions between WIMPs and normal matter are rare and extremely difficult to detect, especially because a constant rain of cosmic radiation from space can drown out the faint signals. That's why LUX is searching for WIMPs 4,850 feet underground in the Sanford Lab, where few cosmic ray particles can penetrate. The detector is further protected from background radiation from the surrounding rock by immersion in a tank of ultra-pure water, which was designed and instrumented by the UC Davis team.
At the heart of the experiment is a 6-foot-tall titanium tank filled with about a third of a ton of liquid xenon, cooled to minus 150 degrees Fahrenheit. If a WIMP strikes a xenon atom it recoils from other xenon atoms and emits photons (light) and electrons. The electrons are drawn upward by an electrical field and interact with a thin layer of xenon gas at the top of the tank, releasing more photons.
Light detectors in the top and bottom of the tank are each capable of detecting a single photon, so the locations of the two photon signals – one at the collision point, the other at the top of the tank – can be pinpointed to within a few millimeters. The energy of the interaction can be precisely measured from the brightness of the signals.
Installed in the summer of 2012, the experiment was filled with liquid xenon in February, and its first run of three months was conducted this spring and summer, followed by intensive analysis of the data. The dark matter search will continue through the next two years.
The Sanford Lab is a state-owned facility and the U.S. Department of Energy supports its operation. The LUX scientific collaboration, supported by the National Science Foundation and DOE, includes 17 research universities including UC Davis and national laboratories in the U.S., the United Kingdom and Portugal.
South Dakota Gov. Dennis Daugaard said his state is proud to play a role in this important research. Homestake Mining Co. donated its gold mine in Lead to the South Dakota Science and Technology Authority, which reopened it in 2007 with funding from the state Legislature and a $70 million donation from philanthropist T. Denny Sanford.
"We congratulate the LUX researchers, and we look forward to working with dark matter scientists and other partners in the years to come," Daugaard said.
The LUX announcement is major step forward for the Sanford Lab's science program, which Laboratory Director Mike Headley said has its roots in a famous physics experiment installed in the same experiment hall in the 1960s.
"These are the first physics results achieved at Homestake since the Ray Davis solar neutrino experiment, which earned him a Nobel Prize for Physics," Headley said. "I'm very proud of our staff's work to help LUX reach this major milestone."
UC Davis physicists contributed strongly to all aspects of LUX: design, construction, installation, commissioning, calibration, operations and data analysis. Electronics engineer Britt Holbrook, and graduate students Mike Woods and Sergey Uvarov, played leading roles in the areas of electronics and computing. Mechanical engineer John Thomson and graduate student Jeremy Mock oversaw the installation of mechanical supports and the tricky move of the assembled detector to the underground lab. The group was a leader in simulations, with key contributions from Szydagis, and graduate students Melinda Sweany and Nick Walsh. About twenty UC undergraduates have worked on LUX over the past seven years.
Planning for the next-generation dark matter experiment at the Sanford Lab already is under way. Compared to LUX's third of a ton of liquid xenon, the LUX-ZEPLIN, or LZ, experiment would have a 7-ton liquid xenon target inside the same 72,000-gallon tank of pure water used by LUX and a sensitivity about a thousand times higher.
LUX and LZ are among 14 active research groups at the Sanford Lab. Other teams of researchers are planning experiments in physics, geology and biology that could extend the future of the lab for decades.
AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.