The Era of Neutrino Astronomy Has Begun

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Category: Research News

Published: Friday, November 22 2013 09:27

Astrophysicists using a telescope embedded in Antarctic ice have succeeded in a quest to detect and record the mysterious phenomena known as cosmic neutrinos – nearly massless particles that stream to Earth at the speed of light from outside our solar system, striking the surface in a burst of energy that can be as powerful as a baseball pitcher’s fastball. Next they hope to build on the early success of the IceCube Neutrino Observatory to detect the source of these high-energy particles, said Physics Professor Gregory Sullivan, who led the University of Maryland’s 12-person team of contributors to the IceCube Collaboration.

“The era of neutrino astronomy has begun,” Sullivan said as the IceCube Collaboration announced the observation of 28 very high-energy particle events that constitute the first solid evidence for astrophysical neutrinos from cosmic sources.

By studying the neutrinos that IceCube detects, scientists can learn about the nature of astrophysical phenomena occurring millions, or even billions of light years from Earth, Sullivan said. “The sources of neutrinos, and the question of what could accelerate these particles, has been a mystery for more than 100 years. Now we have an instrument that can detect astrophysical neutrinos. It’s working beautifully, and we expect it to run for another 20 years.”

The collaboration’s report on the first cosmic neutrino records from the IceCube Neutrino Observatory, collected from instruments embedded in one cubic kilometer of ice at the South Pole, was published Nov. 22 on the cover of Science.

“This is the first indication of very high-energy neutrinos coming from outside our solar system,” said University of Wisconsin-Madison Physics Professor Francis Halzen, principal investigator of IceCube. “It is gratifying to finally see what we have been looking for. This is the dawn of a new age of astronomy.”

“Neutrinos are one of the basic building blocks of our universe,” said UMD Physics Associate Professor and Director Kara Hoffman, an IceCube team member. Billions of them pass through our bodies unnoticed every second. These extremely high-energy particles maintain their speed and direction unaffected by magnetic fields. The vast majority of neutrinos originate either in the sun or in Earth’s own atmosphere. Far more rare are astrophysical neutrinos, which come from the outer reaches of our galaxy or beyond.

The origin and cause of astrophysical neutrinos are unknown, though gamma ray bursts, active galactic nuclei and black holes are potential sources. Better understanding of these neutrinos is critically important in particle physics, astrophysics and astronomy, and scientists have worked for more than 50 years to design and build a high-energy neutrino detector of this type.

IceCube was designed to accomplish two major scientific goals: measure the flux, or rate, of high-energy neutrinos and try to identify some of their sources. The neutrino observatory was built and is operated by an international collaboration of more than 250 physicists and engineers. UMD physicists have been key collaborators on IceCube since 2002, when its unique design was devised and construction began.

IceCube is made up of 5,160 digital optical modules suspended along 86 strings embedded in ice beneath the South Pole. The National Science Foundation-supported observatory detects neutrinos through the tiny flashes of blue light, called Cherenkov light, produced when neutrinos interact in the ice. Computers at the IceCube laboratory collect near-real-time data from the optical sensors and send information about interesting events north via satellite. The UMD team designed the data collection system and much of IceCube's analytic software. Construction took nearly a decade, and the completed detector began gathering data in May 2011.

“IceCube is a wonderful and unique astrophysical telescope – it is deployed deep in the Antarctic ice but looks over the entire Universe, detecting neutrinos coming through the Earth from the northern skies, as well as from around the southern skies,” said Vladimir Papitashvili of the National Science Foundation (NSF) Division of Polar Programs.

In April 2012 IceCube detected two high-energy events above 1 PeV, nicknamed Bert and Ernie, the first astrophysical neutrinos definitively recorded by a terrestrial detector. After Bert and Ernie were discovered, the IceCube team searched their records from May 2010 to May 2012 of events that fell slightly below the energy level of their original search. They discovered 26 more high-energy events, all at levels of 30 teraelectronvolts (TeV) or higher, indicative of astrophysical neutrinos. Preliminary results of this analysis were presented May 15 at the IceCube Particle Astrophysics Symposium at UW–Madison. The analysis presented in Science reveals a highly statistically significant signal (more than 4 sigma), providing solid evidence that IceCube has successfully detected high-energy extraterrestrial neutrinos, said UMD’s Sullivan.

Since astrophysical neutrinos move in straight lines unimpeded by outside forces, they can act as pointers to the place in the galaxy where they originated. The 28 events recorded so far are too few to point to any one location, Sullivan said. Over the coming years, the IceCube team will watch, “like waiting for a long exposure photograph,” as more measurements fill in a picture that may reveal the point of origin of these intriguing phenomena.

New detection systems for astrophysical neutrinos are also in the works. Hoffman is leading the development of the Askaryan Radio Array, a neutrino telescope that uses radio frequency, which transmits best through very cold ice, to detect the particles. Plans are underway for 37 subsurface clusters of radio antennae

The IceCube Neutrino Observatory was built under a NSF Major Research Equipment and Facilities Construction grant, with assistance from partner funding agencies around the world. The NSF's Division of Polar Programs and Physics Division continue to support the project with a Maintenance and Operations grant, along with international support from participating institutes and their funding agencies.

UMD contributors to the IceCube collaboration include Sullivan and Hoffman; faculty and staff members Erik Blaufuss, John Felde, Jordan Goodman, Henrike Wissing, Alex Olivas, Donald La Dieu, and Torsten Schmidt; and graduate students Elim Cheung, Robert Hellauer, Ryan Maunu, and Michael Richman.

Ellen Williams Nominated to Key Administration Post

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Category: Department News

Published: Wednesday, November 13 2013 08:39

Ellen Williams has been nominated by President Obama to the key administration post of Director of the Advanced Research Projects Agency-Energy, Department of Energy. ARPA-E was created to nurture high risk high payoff research that has the potential to make a large impact for the nation especially in the area of technology, jobs, energy, and sustainability.

The White House press release states that "Dr. Ellen D. Williams is the Chief Scientist for BP, a position she has held since 2010. She is currently on a leave of absence from the University of Maryland where she has served as a Distinguished University Professor in the Department of Physics and the Institute for Physical Science and Technology since 2000. Dr. Williams has served as a Professor in the Department of Physics at the University of Maryland since 1991. She founded the University of Maryland Materials Research Science and Engineering Center and served as its Director from 1996 through 2009. Dr. Williams received a B.S. in Chemistry from Michigan State University and a Ph.D. in Chemistry from the California Institute of Technology.”

http://www.whitehouse.gov/the-press-office/2013/11/06/president-obama-announces-more-key-administration-posts

Ellen will still be a member of the Department and IPST, on leave from the University.

Ed Ott in the News

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Category: Department News

Published: Wednesday, October 30 2013 10:45

Two popular press articles highlight a soon to be released Physical Reveiw Letter, co-authored by Ed Ott, regarding an electronic system that exhibits dragon kings. The articles, entitled Physicists Slay 'Dragon Kings and Using Chaos Theory to Predict and Prevent Catastrophic 'Dragon King' Events, appear in the latest issues of Physics World and Wired, respectively.

First Results from LUX

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Category: Research News

Published: Wednesday, October 30 2013 10:15

World’s Most Sensitive Dark Matter Detector

www.sanfordlab.org click image for more information

After its first run of more than three months, operating a mile underground in the Black Hills of South Dakota, a new experiment named LUX has proven itself the most sensitive dark matter detector in the world.

“This result shows that LUX is working quite well”, says Carter Hall, associate professor of physics at the University of Maryland and leader of the Maryland LUX group. “With just a fraction of our final dataset in hand, we’ve produced an important science result, and we’ve demonstrated the promise of the full dataset which we’ll be collecting in the coming years.”

LUX stands for Large Underground Xenon experiment. The scientific collaboration, which is supported by the National Science Foundation and DOE, includes 17 research universities and national laboratories in the United States, the United Kingdom, and Portugal. Researchers from the University of Maryland, including Prof. Hall and graduate students Attila Dobi, Richard Knoche and Jon Balajthy, have played a prominent role in the design, construction, and operation of the detector as well as the recent analysis of the dark matter search data.

Dark matter, so far observed only by its gravitational effects on galaxies and clusters of galaxies, is the predominant form of matter in the universe. Weakly interacting massive particles, or WIMPs – so-called because they rarely interact with ordinary matter except through gravity – are the leading theoretical candidates for dark matter. Theories and results from other experiments suggest that WIMPs could be either “high mass” or “low mass.”

Assuming a high-mass WIMP with a mass of 35 GeV/c2 , LUX has a sensitivity that is more than two times better than any other experiment to directly detect dark matter. (Physicists express the mass of subatomic particles in electron volts (eV) divided by the speed of light squared (c2 ) A giga-electron volt (GeV) is a billion electron volts). LUX also has greatly enhanced sensitivity to low-mass WIMPs, whose possible detection has been suggested by other experiments. Three candidate WIMP events recently reported in ultra-cold silicon detectors, however, 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,” Dan McKinsey of Yale University says. “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.

At the heart of the experiment is a 6-foot-tall titanium tank filled with almost 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.

“LUX is a complex instrument,” says McKinsey, “but it insures that each WIMP event’s unique signature of position and energy will be precisely recorded.”

LUX’s biggest advantage as a dark matter detector is its size, a large xenon target whose outer regions further shield the interior from gamma rays and neutrons. Installed in the Sanford Lab 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 universe's mysterious dark sector presents us with two of the most thrilling challenges in all of physics," says Saul Perlmutter of DOE’s Lawrence Berkeley National Laboratory (Berkeley Lab), a winner of the 2011 Nobel Prize in Physics for discovering the accelerating expansion of the universe. "We call it the dark sector precisely because we don't know what accounts for most of the energy and mass in the universe. Dark energy is one challenge, and as for the other, the LUX experiment's first data now take the lead in the hunt for the dark matter component of the dark sector."

South Dakota Gov. Dennis Daugaard says 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 says.

The LUX announcement is major step forward for the Sanford Lab’s science program, which Laboratory Director Mike Headley points out 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 says. “I’m very proud of our staff’s work to help LUX reach this major milestone.”