![]() ![]() ![]() ![]() UC postdocs Tom Banks and Tommy O'Donnell, who also have joint appointments with the Nuclear Science Division at Berkeley Lab, led the international team of physicists, engineers, and technicians to assemble over ten thousand parts into towers in nitrogen-filled glove boxes, including and bonding almost 8000 25-micron gold wires to 100-micron sized pads on the temperature sensors and on copper pads connected to detector wiring. In addition, Berkeley Lab designed and fabricated the highly sensitive temperature sensors – Neutron Transmutation Doped thermistors invented by Eugene Haller, UC Berkeley faculty and senior faculty scientist in the Material Science Division. The team expects that they would be able to see evidence of the rare radioactive process within these cube-shaped crystals because the phenomenon would produce a barely detectable temperature rise, picked up by highly sensitive temperature sensors.īerkeley Lab, with Lawrence Livermore National Lab, has supplied roughly half the crystals for the CUORE project. Fifty-two crystals, each a little smaller than a Rubik's cube, make up each tower. To detect neutrinoless double-beta decay, the team is using a detector made of 19 independent towers of tellurium dioxide (TeO2) crystals. Detection of this process would allow researchers to demonstrate, for the first time, that neutrinos are their own antiparticles, thereby offering a possible explanation for the abundance of matter over anti-matter in our universe -in other words, why the galaxies, stars, and ultimately people exist in the universe at all. The goal of CUORE is to observe a hypothesized rare process called neutrinoless double-beta decay. The ultimate purpose for the coldest cubic meter in the universe is to house a new ultra-sensitive detector. In order to achieve such a low-temperature cryostat, the team used a multi chamber design that looks something like Russian nesting dolls: six chambers in total, each becoming progressively smaller and colder. The claim that no other object of similar size and temperature – either natural or man-made – exists in the universe was detailed in a recent paper by Jonathan Ouellet, Berkeley Lab Nuclear Science staff and UC Berkeley graduate student. An international team of physicists, including students and postdoctoral scholars from Italy and the US, worked for over two years to assemble the cryostat, iron out the kinks, and demonstrate its record-breaking performance. The chamber, technically called a cryostat, was designed and built in Italy, and maintained the ultra-cold temperature for more than two weeks. Nothing in the universe this large has ever been as cold." We've exceeded our goal of 10 milliKelvin. "This is a tremendous feat of cryogenics. spokesperson for the CUORE collaboration. "We've been building this experiment for almost ten years," says Yury Kolomensky, senior faculty scientist in the Physics Division of Berkeley Lab, professor of physics at UC Berkeley, and U.S. The CUORE collaboration is made of 157 scientists from the U.S., Italy, China, Spain, and France, and is based in the underground Italian facility called Laboratori Nazionali del Gran Sasso (LNGS) of the INFN. Lawrence Berkeley National Lab (Berkeley Lab) manages the CUORE project in the US. The collaboration responsible for the record-setting refrigeration is called the Cryogenic Underground Observatory for Rare Events (CUORE), supported jointly by the Istituto Nazionale di Fisica Nucleare (INFN) in Italy, and the Department of Energy's Office of Science and National Science Foundation in the US. ![]()
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