 |
|
Researchers detect low-energy neutrinos, probe energy production in sun's center
August 28, 2007Blacksburg, Va. -- In collaboration with scientists from institutions in the United States and Europe, researchers from Virginia Tech have observed tell-tale signals of neutrinos emitted by thermonuclear fusion reactions that power the sun deep in its interior. At approximately 15 million degrees, protons - the nuclei of hydrogen atoms - and light elements can fuse to form new nuclei. Several such steps eventually convert the hydrogen in the sun into helium, releasing about 25 million times more energy per gram than TNT, oil, or coal.
"While the neutrinos, which are uncharged elementary particles, only take about eight minutes to reach the earth, the thermal energy produced at the center of the sun only appears as sunlight some 50 thousand years later, after diffusing to the sun's surface," said Bruce Vogelaar professor of physics and leader of Virginia Tech's research team for this project.
"The only way to prove the validity of this model of solar energy generation is to observe these neutrinos which easily travel right through the sun because of their weak interaction with matter," Vogelaar said. "Of special interest are those neutrinos from the decay of 7Be, a critical step in the energy chain of the sun."
It is these neutrinos that the Virginia Tech team and their colleagues have observed directly for the first time in the Borexino detector, located under the Gran Sasso peak in the Apennine mountain range about 100 miles east of Rome. Borexino is a massive detector that contains some 350,000 gallons of organic liquid. Its central region detects neutrinos by seeing the light given off when a neutrino collides with an electron, using some 2,200 photosensors arrayed around the detector.
"The sun emits copious amounts of neutrinos in a wide range of energies," Vogelaar said. "About 10 billion pass through your thumbnail each second."
In the last decade, the much rarer high-energy fraction (one part in ten thousand) has been seen in many experiments, he said. The vast majority of the flux, however, is at much lower energies and had not been directly observed until now. This is because previous detector technologies were unable to discriminate low-energy neutrino signals from formidable backgrounds due to radioactivities normally present in the environment. These include the detector itself and cosmic rays. To avoid the latter, the detector was shielded by placing it deep underground at Gran Sasso. The Borexino Collaboration has developed and employed a new technology that virtually eliminated even trace contaminations, allowing successful measurement of the low-energy solar neutrinos.
The required purities are unprecedented - several million times lower than levels normally achievable, even with the development of ultra-clean technologies for the semiconductor industry. Another major problem with detecting low-energy neutrinos was the inescapable carbon in the detector's organic liquid, which normally contains a million times more radioactive 14C than tolerable for Borexino. 14C is normally used in radiocarbon dating studies.
Raju Raghavan, professor of physics at Virginia Tech and formerly with Bell Laboratories, made the first breakthrough in methods for reducing radioactive contamination sufficiently as well as discovering how to avoid the radiocarbon. With colleagues from University of Pavia, Italy, he invented new methods of purification and material characterization that explicitly showed for the first time that the solubility of heavy metals, such as radioactive Uranium and Thorium, in non-polar liquids were a million times lower than thought earlier, and thus suitable for Borexino. Since radiocarbon cannot be chemically purified from normal carbon, Raghavan side-stepped the problem by postulating that petrochemicals derived organic liquids ought to contain much less radiocarbon than normal, due to their residence deep in the earth for geological times. Raghavan and colleagues from the University of Toronto developed a method to show this was the case, and that indeed, the purities reached Borexino levels, which are parts per million billion.
"These results on the laboratory scale showed the potential for low-energy neutrino spectroscopy in Borexino and paved the way to large scale investments for the experiment," Raghavan said. "These new techniques have also impacted commercial technology needed today," For example, he solved the sodium contamination problem in photolithographic chemistry in the fabrication of chips in the microelectronic industry using these techniques.
Showing that these results were valid at the ton, and then kiloton, scales was accomplished over the next 10 years by the Borexino collaboration, including exhaustive field tests using a five-ton prototype detector constructed in Gran Sasso.
The Borexino collaboration consists of more than 100 scientists, post-doctoral fellows, and students from Tech and Princeton University in the U.S., and groups from Italy, France, Germany, Russia, and Poland. In addition to Vogelaar and Raghavan, other members of the Virignia Tech team were Henning Back (currently at NCSU), Christian Grieb, Steven Hardy, Matthew Joyce, Derek Rountree, and. Szymon Manecki, along with several undergraduates. The collaboration is led by Gianpaolo Bellini of the University of Milan, Italy. Essential support for the 20-year effort was provided by the Laboratori Nazionali del Gran Sasso, the INFN (Italy), the National Science Foundation, and other funding agencies in Europe and Russia.
"The scientific and technological achievement of Borexino is a testament to the value of international collaboration and the ingenuity and tenacity of the Borexino collaboration over 20 years to achieve the present success." Vogelaar said. "We expect that information on the 7Be solar neutrinos will clarify the sun's energy cycle in great detail and throw light on the nature of the neutrino itself"
Virginia Tech
It is these neutrinos that the Virginia Tech team and their colleagues have observed directly for the first time in the Borexino detector, located under the Gran Sasso peak in the Apennine mountain range about 100 miles east of Rome. Borexino is a massive detector that contains some 350,000 gallons of organic liquid. Its central region detects neutrinos by seeing the light given off when a neutrino collides with an electron, using some 2,200 photosensors arrayed around the detector.
"The sun emits copious amounts of neutrinos in a wide range of energies," Vogelaar said. "About 10 billion pass through your thumbnail each second."
In the last decade, the much rarer high-energy fraction (one part in ten thousand) has been seen in many experiments, he said. The vast majority of the flux, however, is at much lower energies and had not been directly observed until now. This is because previous detector technologies were unable to discriminate low-energy neutrino signals from formidable backgrounds due to radioactivities normally present in the environment. These include the detector itself and cosmic rays. To avoid the latter, the detector was shielded by placing it deep underground at Gran Sasso. The Borexino Collaboration has developed and employed a new technology that virtually eliminated even trace contaminations, allowing successful measurement of the low-energy solar neutrinos.
The required purities are unprecedented - several million times lower than levels normally achievable, even with the development of ultra-clean technologies for the semiconductor industry. Another major problem with detecting low-energy neutrinos was the inescapable carbon in the detector's organic liquid, which normally contains a million times more radioactive 14C than tolerable for Borexino. 14C is normally used in radiocarbon dating studies.
Raju Raghavan, professor of physics at Virginia Tech and formerly with Bell Laboratories, made the first breakthrough in methods for reducing radioactive contamination sufficiently as well as discovering how to avoid the radiocarbon. With colleagues from University of Pavia, Italy, he invented new methods of purification and material characterization that explicitly showed for the first time that the solubility of heavy metals, such as radioactive Uranium and Thorium, in non-polar liquids were a million times lower than thought earlier, and thus suitable for Borexino. Since radiocarbon cannot be chemically purified from normal carbon, Raghavan side-stepped the problem by postulating that petrochemicals derived organic liquids ought to contain much less radiocarbon than normal, due to their residence deep in the earth for geological times. Raghavan and colleagues from the University of Toronto developed a method to show this was the case, and that indeed, the purities reached Borexino levels, which are parts per million billion.
"These results on the laboratory scale showed the potential for low-energy neutrino spectroscopy in Borexino and paved the way to large scale investments for the experiment," Raghavan said. "These new techniques have also impacted commercial technology needed today," For example, he solved the sodium contamination problem in photolithographic chemistry in the fabrication of chips in the microelectronic industry using these techniques.
Showing that these results were valid at the ton, and then kiloton, scales was accomplished over the next 10 years by the Borexino collaboration, including exhaustive field tests using a five-ton prototype detector constructed in Gran Sasso.
The Borexino collaboration consists of more than 100 scientists, post-doctoral fellows, and students from Tech and Princeton University in the U.S., and groups from Italy, France, Germany, Russia, and Poland. In addition to Vogelaar and Raghavan, other members of the Virignia Tech team were Henning Back (currently at NCSU), Christian Grieb, Steven Hardy, Matthew Joyce, Derek Rountree, and. Szymon Manecki, along with several undergraduates. The collaboration is led by Gianpaolo Bellini of the University of Milan, Italy. Essential support for the 20-year effort was provided by the Laboratori Nazionali del Gran Sasso, the INFN (Italy), the National Science Foundation, and other funding agencies in Europe and Russia.
"The scientific and technological achievement of Borexino is a testament to the value of international collaboration and the ingenuity and tenacity of the Borexino collaboration over 20 years to achieve the present success." Vogelaar said. "We expect that information on the 7Be solar neutrinos will clarify the sun's energy cycle in great detail and throw light on the nature of the neutrino itself"
Virginia Tech
Neutrinos Current Events and Neutrinos News RSSRutgers physicists discover novel electronic properties in two-dimensional carbon structure
Rutgers researchers have discovered novel electronic properties in two-dimensional sheets of carbon atoms called graphene that could one day be the heart of speedy and powerful electronic devices.
Prototype developed to detect dark matter
A team of researchers from the University of Zaragoza (UNIZAR) and the Institut d'Astrophysique Spatiale (IAS, in France) has developed a "scintillating bolometer", a device that the scientists will use in efforts to detect the dark matter of the Universe, and which has been tested at the Canfranc Underground Laboratory in Huesca, Spain.
Invading black holes explain cosmic flashes
Black holes are invading stars, providing a radical explanation to bright flashes in the universe that are one of the biggest mysteries in astronomy today.
To understand the universe, science calls on the ultrasmall
Will the universe expand outward for all of eternity and end in a vast, dark, cold, sterile, diffuse nothingness? Or will the "Big Bang" - the gargantuan explosion that formed the universe 14 billion years ago - end in the "Big Crunch?"
Ytterbium's Broken Symmetry
Ytterbium was discovered in 1878, but until it recently became useful in atomic clocks, the soft metal rarely made the news. Now ytterbium has a new claim to scientific fame.
Precision measurement of W boson mass portends stricter limits for Higgs particle
Scientists of the DZero collaboration at the Department of Energy's Fermi National Accelerator Laboratory have achieved the world's most precise measurement of the mass of the W boson by a single experiment. Combined with other measurements, the reduced uncertainty of the W boson mass will lead to stricter bounds on the mass of the elusive Higgs boson.
Cosmic rays detected deep underground reveal secrets of the upper atmosphere
Cosmic-rays detected half a mile underground in a disused U.S. iron-mine can be used to detect major weather events occurring 20 miles up in the Earth's upper atmosphere, a new study has revealed.
UD researchers focus on building telescope at South Pole
It's 40 degrees F below zero (with the wind chill) at the South Pole today. Yet a research team from the University of Delaware is taking it all in stride.
Einstein's relativity survives neutrino test
Physicists working to disprove "Lorentz invariance" -- Einstein's prediction that matter and massless particles will behave the same no matter how they're turned or how fast they go -- won't get that satisfaction from muon neutrinos, at least for the time being, says a consortium of scientists.
Crystal bells stay silent as physicists look for dark matter
Scientists of the Cryogenic Dark Matter Search experiment today announced that they have regained the lead in the worldwide race to find the particles that make up dark matter. The CDMS experiment, conducted a half-mile underground in a mine in Soudan, Minn., again sets the world's best constraints on the properties of dark matter candidates.
More Neutrinos Current Events and Neutrinos News Articles
 |
Neutrino Oscillations: Present Status and Future Plans by Jennifer A. Thomas (Author), Patricia L Vahl (Author), Jennifer A. Thomas (Editor), Patricia L. Vahle (Editor) This book reviews the status of a very exciting field -- neutrino oscillations -- at a very important time. The fact that neutrinos have mass has only been proved in the last few years and the acceptance of that fact has opened up a whole new area of study to understand the fundamental parameters of the mixing matrix. The book summarizes the results from all the experiments which have played a role in the measurement of neutrino oscillations and briefly describes the scope of some new planned experiments. Contributions include a theoretical introduction by Stephen Parke from FNAL, as well as articles from all the major experimental groups who have been pivotal in uncovering the nature of the neutrino mass. Contents: Neutrino Oscillation Phenomenology (S J Parke); The... |
 |
OCZ Neutrino OCZDIY10N1-US 10.1-Inch DIY Netbook by OCZ Technology Based on the Intel Atom processor, the 10.1 Inches Neutrino was developed to push the envelope in the growing area of netbooks as the first DIY offering. Proving that good things come in small packages, the Neutrino provides all the day-to-day file viewing and web-surfing needs for on-the-go traveling, education, office or home use. Equipped with a built-in camera and microphone, Neutrino will expand your horizons through communications between family, friends, and colleague, infinite possibilities.Though many companies offer customization and different configurations, nothing compares to the options available to you with a DIY notebook kit. When the components and features are selected by you and it's built by you, it's more like you. |
 |
The Hotel Child by Ingrid Lucia and The Flying Neutrinos Among the swing revivalists--from the Squirrel Nut Zippers to Royal Crown Revue and Lavay Smith & Her Red Hot Skillet Lickers--no musician can chart his or her pedigree back the way singer Ingrid Lucia and bassist Todd Londagin can. As kids, the story goes, the pair were members of the Flying Neutrinos Family band, living in hotels, playing swing on rafts, and, likely, storing key data for their own Flying Neutrinos. The Hotel Child is the third effort by Lucia, Londagin, guitarist Matt Munisteri, bassist Matt Weiner, and a handful of assorted horns, drums, and accordion. Their music bumps with a sprightly step, buoyed by Lucia's early-Billie Holiday tinged voice and the band's languid looseness. Their brand of swing isn't hyped up with bombastic horn charts or even slicked up like the... |
 |
Reload (feat. Neutrino) Neutrino Chipmunk (Primary Contributor) |
 |
Teenage Mutant Ninja Turtles Zak, The Neutrino by Playmates Teenage Mutant Ninja Turtles Zak The Neutrino |
|
Black Diamond - Neutrino Carabiner (2nd) - Purple by Black Diamond | |
 |
Physics of Neutrinos by Masataka Fukugita (Author), Tsutomu Yanagida (Author) This book provides a survey of the current state of research into the physics of neutrinos. It is presented in a pedagogical form accessible to non-specialists and graduate students, but will also be useful as a handbook for researchers in this field. The reader finds here a global view of the areas of physics in which neutrinos play important roles, including astrophysics and cosmology. The book is intended to be self-contained: Starting from the standard theory of electroweak interactions, the key notions are explained in detail and the fundamental equations are derived explicitly, so that readers can understand their precise content and implications. Prime emphasis is given to models of massive neutrinos and to the magnetic moment of the neutrino. The first eight chapters deal mostly... |
 |
OCZ Neutrino 10 inch Netbook CaseCrown Double Memory Foam Netbook Pouch (Black Faux Suede) by CaseCrown The CaseCrown Double Memory Foam Netbook Pouch provides perfect protection for your Netbook. It is made of premium quality, shock absorbing, double memory foam to enhance protection for your netbook even though it is very light and thin. The internal supporting bands securely hold your netbook in place even as you're using the netbook! This faux suede Netbook Pouch is the elegant solution for modern professionals and students in any occasion. |
 |
OCZ Neutrino OCZDIY10N1 10" (BLUE) Netbook Laptop Zipper Sleeve Bag by Gizmo Dorks Protect your laptop and carry all your accessories with you, a convenient front zipper pouch allows you to store your chargers and any documents you may have. Interior pouch allows you to store memory sticks, flash drives, thumb drives, or even Wi-fi sticks. |
 |
Rab Neutrino Endurance Down Jacket - Men's by Rab Whiteout conditions and sub-zero temps at basecamp demand the unparalleled warmth and protection served up by the Rab Mens Neutrino Endurance Down Jacket. Stuffed with premium 850-fill goose down and wrapped with waterproof Pertex Endurance shell fabric, this highly weather resistant puffy keeps cold, snowy conditions at bay while you wait out the storm. Despite its massive amount of lofty warmth, the Neutrino packs down small when youre on the move thanks to the included stuff sack. Product FeaturesMaterial: [Shell] Pertex Endurance; [Lining] Pertex QuantumInsulation: 850-Fill downHood: YesPockets: 2 Hand, 1 internal zipWaterproof: Highly water-resistantWeight: 22oz (625g)Recommended Use: Mountaineering, expeditionsManufacturer Warranty: 1... |
| © 2009 BrightSurf.com |