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  • richardmitnick 8:46 am on April 28, 2014 Permalink | Reply
    Tags: , Jefferson National Accelerator Lab, , Symmetry Breaking Studies   

    From DOE Pulse: “Quarks in the looking glass” 

    pulse

    D.O.E. Pulse

    April 28, 2014
    Submitted by DOE’s Thomas Jefferson Accelerator Facility

    From matching wings on butterflies to the repeating six-point pattern of snowflakes, symmetries echo through nature, even down to the smallest building blocks of matter. Since the discovery of quarks, the building blocks of protons and neutrons, physicists have been exploiting those symmetries to study quarks’ intrinsic properties and to uncover what those properties can reveal about the physical laws that govern them.

    mirror
    Elementary particles behave differently in the mirror world. Graphic: Jefferson Lab

    A recent experiment carried out at DOE’s Jefferson Lab to study a rare instance of symmetry breaking in electron-quark scattering has provided a new determination of an intrinsic property of quarks that’s five times more precise than the previous measurement.

    The result has also set new limits, in a way complementary to high-energy colliders such as the Large Hadron Collider at CERN, for the energies that researchers would need to access physics beyond the Standard Model.

    LHC Grand Tunnel
    LHC

    sm
    The Standard Model of elementary particles, with the three generations of matter, gauge bosons in the fourth column, and the Higgs boson in the fifth.

    The Standard Model is a well-tested theory that, excluding gravity, describes the subatomic particles and their interactions, and physicists believe that peering beyond the Standard Model may help resolve many unanswered questions about the origins and underlying framework of our universe.

    The experiment probed properties of the mirror symmetry of quarks. In mirror symmetry, the characteristics of an object remain the same even if that object is flipped as though it were reflected in a mirror.

    The mirror symmetry of quarks can be probed by gauging their interactions with other particles through fundamental forces. Three of the four forces that mediate the interactions of quarks with other particles – gravity, electromagnetism and the strong force – are mirror-symmetric. However, the weak force – the fourth force – is not. That means that the intrinsic characteristics of quarks that determine how they interact through the weak force (called the weak couplings) are different from, for example, the electric charge for the electromagnetic force, the color charge for the strong force, and the mass for gravity.

    In Jefferson Lab’s Experimental Hall A, experimenters measured the breaking of the mirror symmetry of quarks through the process of deep-inelastic scattering. A 6.067 GeV beam of electrons was sent into deuterium nuclei, the nuclei of an isotope of hydrogen that contain one neutron and one proton each (and thus an equal number of up and down quarks).

    “When it’s deep-inelastic scattering, the momentum carried by the electron goes inside the nucleon and breaks it apart,” said Xiaochao Zheng, an associate professor of physics at the University of Virginia and a spokesperson for the collaboration that conducted the experiment.

    To produce the effect of viewing the quarks through a mirror, half of the electrons sent into the deuterium were set to spin along the direction of their travel (like a right-handed screw), and the other half were set to spin in the opposite direction. About 170,000 million electrons that interacted with quarks in the nuclei through both the electromagnetic and the weak forces over a two-month period of running were identified in two High Resolution Spectrometers.

    “This is called an inclusive measurement, but that just means that you only measure the scattered electrons. So, we used both spectrometers, but each detecting electrons independently from the other. The challenging part is to identify the electrons as fast as they come,” Zheng said.

    The experimenters found an asymmetry, or difference, in the number of electrons that interacted with the target when they were spinning in one direction versus the other. This asymmetry is due to the weak force between the electron and quarks in the target. The weak force experienced by quarks has two components. One is analogous to electric charge and has been measured well in previous experiments. The other component, related to the spin of the quark, has been clearly isolated for the first time in the Jefferson Lab experiment.

    Specifically, the present result led to a determination of the effective electron-quark weak coupling combination 2C2u – C2d that is five times more precise than previously determined. This particular coupling describes how much of the mirror-symmetry breaking in the electron-quark interaction originates from quarks’ spin preference in the weak interaction. The new result is the first to show that this combination is non-zero, as predicted by the Standard Model.

    The last experiment to access this coupling combination was E122 at DOE’s Stanford Linear Accelerator Center (now SLAC National Accelerator Laboratory). Data from that experiment were used to establish the newly theorized Standard Model more than 30 years ago.

    SLAC Campus
    SLAC

    The good agreement between the new 2C2u – C2d result and the Standard Model also indicates that experimenters must reach higher energy limits in order to potentially find new interactions beyond the Standard Model with respect to the violation of mirror symmetry due to the spin of the quarks. The new limits, 5.8 TeV and 4.6 TeV, are within reach of the Large Hadron Collider at CERN, but the spin feature provided by this experiment cannot be identified cleanly in collider experiments.

    In the meantime, the researchers plan to extend this experiment in the next era of research at Jefferson Lab. In a bid to further refine the knowledge of quarks’ mirror-symmetry breaking, experimenters will use Jefferson Lab’s upgraded accelerator to nearly double the energy of the electron beam, reducing their experimental errors and improving the precision of the measurement by five to ten times the current value. The experiment will be scheduled following completion of the upgrade in 2017.

    The experiment was funded by the DOE Office of Science, the National Science Foundation Division of Physics and the Jeffress Memorial Trust, as well as with support provided to individual researchers by their home institutions. Nearly 100 researchers from more than 30 institutions collaborated on the experiment, including two DOE National Labs, Jefferson Lab and Argonne National Lab. The result was published in the Feb. 6 edition of Nature.

    See the full article here.

    DOE Pulse highlights work being done at the Department of Energy’s national laboratories. DOE’s laboratories house world-class facilities where more than 30,000 scientists and engineers perform cutting-edge research spanning DOE’s science, energy, National security and environmental quality missions. DOE Pulse is distributed twice each month.

    DOE Banner


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  • richardmitnick 9:06 am on February 11, 2014 Permalink | Reply
    Tags: , , , Jefferson National Accelerator Lab, ,   

    From Symmetry: “Quarks in the looking glass” 

    February 10, 2014
    Kandice Carter

    A recent experiment at Jefferson Lab probed the mirror symmetry of quarks, determining that one of their intrinsic properties is non-zero—as predicted by the Standard Model.
    sm
    Standard Model of Particle Physics

    From matching wings on butterflies to the repeating six-point pattern of snowflakes, symmetries echo through nature, even down to the smallest building blocks of matter. Since the discovery of quarks, the building blocks of protons and neutrons, physicists have been exploiting those symmetries to study quarks’ intrinsic properties and to uncover what those properties can reveal about the physical laws that govern them.

    A recent experiment carried out at Jefferson Lab has provided a new determination of an intrinsic property of quarks that’s five times more precise than the previous measurement.

    jlab
    Courtesy of Jefferson Lab

    The result has also set new limits, in a way complementary to such as the Large Hadron Collider at CERN, for the energies that researchers would need to access physics beyond the Standard Model. The Standard Model is a well-tested theory that, excluding gravity, describes the subatomic particles and their interactions, and physicists believe that peering beyond the Standard Model may help resolve many unanswered questions about the origins and underlying framework of our universe. The result was published in the February 6 edition of Nature.

    CERN

    CERN LHC New
    LHC

    The experiment probed properties of the mirror symmetry of quarks. In mirror symmetry, the characteristics of an object remain the same even if that object is flipped as though it were reflected in a mirror.

    The mirror symmetry of quarks can be probed by gauging their interactions with other particles through fundamental forces. Three of the four forces that mediate the interactions of quarks with other particles—gravity, electromagnetism and the strong force—are mirror-symmetric. However, the weak force—the fourth force—is not. That means that the intrinsic characteristics of quarks that determine how they interact through the weak force (called the weak couplings) are different from, for example, the electric charge for the electromagnetic force, the color charge for the strong force, and the mass for gravity.

    jlab
    Info-Graphic by: Jefferson Lab

    In Jefferson Lab’s Experimental Hall A, experimenters measured the breaking of the mirror symmetry of quarks through the process of deep-inelastic scattering. A 6.067 billion-electronvolt beam of electrons was sent into deuterium nuclei, the nuclei of an isotope of hydrogen that contain one neutron and one proton each (and thus an equal number of up and down quarks).

    “When it’s deep-inelastic scattering, the momentum carried by the electron goes inside the nucleon and breaks it apart,” says Xiaochao Zheng, an associate professor of physics at the University of Virginia and a spokesperson for the collaboration that conducted the experiment.

    To produce the effect of viewing the quarks through a mirror, half of the electrons sent into the deuterium were set to spin along the direction of their travel (like a right-handed screw), and the other half were set to spin in the opposite direction. Researchers identified about 170,000 million electrons that interacted with quarks in the nuclei through both the electromagnetic and the weak forces over a two-month period of running.

    “This is called an inclusive measurement, but that just means that you only measure the scattered electrons. So, we used both spectrometers, but each detecting electrons independently from the other. The challenging part is to identify the electrons as fast as they come,” Zheng says.

    The experimenters found an asymmetry, or difference, in the number of electrons that interacted with the target when they were spinning in one direction versus the other. This asymmetry is due to the weak force between the electron and quarks in the target. The weak force experienced by quarks has two components. One is analogous to electric charge and has been measured well in previous experiments. The other component, related to the spin of the quark, has been clearly isolated for the first time in the Jefferson Lab experiment.

    Specifically, the present result led to a determination of the effective electron-quark weak coupling combination 2C2u–C2d that is five times more precise than previously determined. This particular coupling describes how much of the mirror-symmetry breaking in the electron-quark interaction originates from quarks’ spin preference in the weak interaction. The new result is the first to show that this combination is non-zero, as predicted by the Standard Model.

    The last experiment to access this coupling combination was E122 at SLAC National Accelerator Laboratory. Data from that experiment were used to establish the newly theorized Standard Model more than 30 years ago.

    The good agreement between the new 2C2u–C2d result and the Standard Model also indicates that experimenters must reach higher energy limits in order to potentially find new interactions beyond the Standard Model with respect to the violation of mirror symmetry due to the spin of the quarks. The new limits, 5.8 and 4.6 trillion electronvolts, are within reach of the Large Hadron Collider at CERN, but the spin feature provided by this experiment cannot be identified cleanly in collider experiments.

    In the meantime, the researchers plan to extend this experiment in the next era of research at Jefferson Lab. In a bid to further refine the knowledge of quarks’ mirror-symmetry breaking, experimenters will use Jefferson Lab’s upgraded accelerator to nearly double the energy of the electron beam, reducing their experimental errors and improving the precision of the measurement by five to 10 times the current value. The experiment will be scheduled following completion of the upgrade in 2017.

    See the full article here.

    Symmetry is a joint Fermilab/SLAC publication.



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  • richardmitnick 11:52 am on January 17, 2014 Permalink | Reply
    Tags: , , Jefferson National Accelerator Lab, , Spectrometers   

    From Fermilab: “Fermilab breaks ground on coil fabrication for Jefferson Lab collaboration” 


    Fermilab is an enduring source of strength for the US contribution to scientific research world wide.

    Friday, Jan. 17, 2014
    Sarah Witman

    There is perhaps no greater challenge, mentally, than taking on a project that has been attempted previously but not successfully completed.

    This is the position a team of Fermilab engineers and physicists found themselves in more than a year ago, when Jefferson Lab, based in Virginia, came to Fermilab for help on a project: fabricating magnet coils for an upgrade to its CEBAF Large Acceptance Spectrometer (CLAS) experiment.

    It turned out to be a good move. In late November, a Magnet Systems Department fabrication team in the Technical Division successfully wound a full-size coil, called a practice coil, of the type to be installed in the new torus magnet for the upgrade of Jefferson Lab’s CLAS detector. Jefferson Lab’s upgraded facilities will provide scientists with unprecedented precision and reach for studies of atomic nuclei.

    coil
    The Magnet Systems Department recently successfully completed a prototype torus magnet coil for the Jefferson Lab CLAS12 upgrade. They devised a relatively inexpensive system, seen here, for winding the 2,500-pound coil. While the price of a standard coil-winding table that can hold a 4,000-pound fixture is $190,000, the Fermilab team built an adequate system for less than $10,000. One layer of coil, sitting at the winding fixture with a 12-foot-diameter cable spool installed above the fixture, and the second spool on the tensioner, is almost completely wound. Photo: Douglas Howard, TD

    “Now we can say we can definitely do this job,” said Fermilab engineer Sasha Makarov. “It seems like Jefferson Lab is very satisfied with our achievement.”

    See the full article here.

    Fermilab Campus

    Fermi National Accelerator Laboratory (Fermilab), located just outside Batavia, Illinois, near Chicago, is a US Department of Energy national laboratory specializing in high-energy particle physics.


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  • richardmitnick 6:06 pm on November 18, 2013 Permalink | Reply
    Tags: , , Jefferson National Accelerator Lab, , ,   

    From Symmetry: “Connecting the visible universe with dark matter” 

    November 18, 2013

    Does the visible photon have a counterpart, a dark photon, that interacts with the components of dark matter?

    Kandice Carter

    For thousands of years, humanity has relied on light to reveal the mysteries of our universe, whether it’s by observing the light given off by brightly burning stars or by shining light on the very small with microscopes.

    Yet, according to recent evidence, scientists think that only about 5 percent of our universe is made of visible matter—ordinary atoms that make up nearly everything we can see, touch and feel. The other 95 percent is composed of the so-called dark sector, which includes dark matter and dark energy. These are described as “dark” because we observe their effects on other objects rather than by seeing them directly. Now, to study the dark, scientists are turning to what they know about light, and they are pointing to a recently successful test of experimental equipment that suggests an exploration of the dark sector may be possible at Jefferson Lab.

    Dark light

    darklight
    Illustration by Sandbox Studio, Chicago

    We know that the particles of light, photons, interact with visible matter and its building blocks—protons, neutrons and electrons. Perhaps the same is true for dark matter. In other words, does the visible photon have a counterpart, a dark photon, that interacts with the components of dark matter?

    The DarkLight collaboration is hoping to answer that question. Peter Fisher and Richard Milner, professors at the Massachusetts Institute of Technology, serve as spokespersons for the DarkLight collaboration. Fisher was recently appointed head of the MIT physics department, and Milner is director for the institute’s Laboratory of Nuclear Science.

    In a recent interview, Milner said that the dark photon may bridge the dark and light sectors of our universe.

    “Such particles are motivated by the assumption that dark matter exists and that it must somehow couple to the standard matter in the universe. And these dark photons kind of straightforwardly could do that,” he explains.

    According to theory, the dark photon is very similar to the light photon, except that it has mass and interacts with dark matter. The dark photon is sometimes referred to as a heavy photon or as a particle dubbed the A’ (pronounced “A prime”). If the dark photon also interacts with ordinary matter, it may be coaxed out of hiding under just the right conditions. In fact, Milner says that scientists may have already caught glimpses of the effects of dark photons in data from particle physics and astrophysics experiments.

    Hints of dark photons in data past

    For instance, dark photons may play a role in explaining the data in the Muon g-2 experiment (pronounced “Moo-on g minus two experiment”) that was conducted at Brookhaven National Laboratory in 2001. Muons are particles that can be thought of as heavier cousins of electrons.

    The Muon g-2 experiment sought to measure a characteristic of the muon related to its magnetic field. In simplistic terms, an item’s magnetic moment quantifies the strength of its reaction to a magnetic field. The muon has a magnetic moment, but, unlike your typical chunk of steel, the muon’s magnetic moment is altered by its tiny size—this alteration is captured in the muon’s so-called “anomalous magnetic moment.” When the Muon g-2 collaboration measured the muon’s anomalous magnetic moment, its collaborators were surprised to find that the number they they measured didn’t match the number they expected.

    “If this is real, such a discrepancy could be explained by a dark photon of the type and mass that DarkLight is searching for,” Milner says.

    Other evidence of dark photons may be found in astrophysics.

    When a measurement was made of high-energy electron–positron pairs in outer space, there were more than could be explained by production from cosmic rays, suggesting that something else, such as dark photons, produces extra pairs.

    “Also, there are indications from the center of our galaxy that there is radiation which might be consistent with the dark photon,” Milner adds.

    A challenging experiment

    If dark photons are giving rise to these observed phenomena, it means that they do interact with visible matter, if ever so rarely. It also means that the effect should be reproducible and measurable by experimenters.

    “This dark photon that we expect could be seen by emission from a charged particle beam, like an electron beam. So an electron beam can radiate such a dark photon,” Milner explains. “So, we looked around, and the world’s most powerful electron beam is at the Jefferson Lab Free-Electron Laser. It has about 1 megawatt of power in the beam. And so that’s how we arrived at Jefferson Lab; it’s absolutely unique in the world.”

    The scientists drafted a proposal that calls for aiming the beam at the protons in a target of hydrogen gas. MIT theorist Jesse Thaler, whose group has carried out important calculations for DarkLight, proposed the name for the experiment, based on the method that will be used to carry it out (DarkLight: Detecting a Resonance Kinematically with Electrons Incident on a Gaseous Hydrogen Target).

    The experimenters chose hydrogen, because its atoms consist of just one proton with an orbiting electron. When the electrons from the accelerator strike the protons in the hydrogen, they’ll knock the protons out of the target.

    “So if we do it at sufficiently low energies, we know the final state is simple—it’s just the scattered electron, the proton and the electron–positron pair, which could come from this decay of the dark photon,” Milner explains.

    The experiment was approved on the condition that the collaboration could show that they were up to the technical challenges of conducting it. Milner says the main challenge was to prove that the accelerator operators could get an electron beam through the narrow hydrogen target. Even though the electrons in the beam would have low energies, the beam would have a lot of them, amounting to 1 megawatt of power. That much power would destroy any container used to hold the hydrogen gas.

    The experimenters decided that the gas would be pumped into a narrow pipe. The electrons would then be threaded into that same narrow pipe. At its narrowest, the pipe would need to be about 2 millimeters wide and 5 centimeters long, which is roughly the size of a round coffee stirrer.

    “We decided that we really needed to do a test with a beam. So, we basically built a system, a test target system that had basically a mock-up of apertures, 2-millimeter-, 4-millimeter- and 6-millimeter-diameter apertures, in an aluminum block. And we brought it to Jefferson Lab about a year ago. And in late July, we had a test,” he says.

    jlab
    Jefferson Lab laser accelerator operators threaded an electron beam through a small tube the size of a coffee stirrer inside this apparatus to show that the DarkLight experiment was possible. DarkLight will search for dark photons, which are particles that interact with both dark matter and visible matter. Courtesy of: Jefferson Lab

    Threading the coffee stirrer

    The staff at MIT-Bates Research and Engineering Center designed, constructed and delivered the test target assembly. The Jefferson Lab accelerator operators and a team from the DarkLight collaboration attempted to thread the electron beam through the narrow pipes in the aluminum block, successfully threading the beam through the 6-millimeter, then the 4-millimeter, and finally the 2-millimeter mock targets. What’s more, the electrons in the beam passed through the pipes cleanly. In the case of the smallest aperture, 2 millimeter, the operators threaded the electrons through the pipe continuously over a period of seven hours; in that time, only three electrons were lost as they struck the walls of the pipe for every million that passed cleanly through.

    “So, it’s a very powerful beam, it’s a very bright beam, but it’s also a very clean beam,” Milner says.

    The DarkLight collaboration recently published the results of the successful tests in Physical Review Letters.

    With this successful test, the DarkLight experiment has been approved for running. Milner says the collaboration has a lot of work ahead of it before it can run the experiment, including building the detectors that will be used to capture the protons, electrons and electron–positron pairs, and finalizing the target.

    In the meantime, there are also other hunts for dark photons that are preparing to run at Jefferson Lab. Two of these experiments will be powered by the same accelerator. The Heavy Photon Search is preparing to run in Jefferson Lab’s Experimental Hall B, and the APEX experiment will be carried out in Experimental Hall A.

    See the full article here.

    Symmetry is a joint Fermilab/SLAC publication.



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  • richardmitnick 3:18 pm on September 17, 2013 Permalink | Reply
    Tags: , Jefferson National Accelerator Lab,   

    From Jefferson Lab: “Proton’s Weak Charge Determined for First Time” 

    Sept. 17, 2013
    No Writer Credit

    Researchers have made the first experimental determination of the weak charge of the proton in research carried out at the Department of Energy’s Thomas Jefferson National Accelerator Facility (Jefferson Lab).

    The results, accepted for publication in Physical Review Letters, also include the determinations of the weak charge of the neutron, and of the up quark and down quark. These determinations were made by combining the new data with published data from other experiments. Although these preliminary figures are the most precise determinations to date, they were obtained from an analysis of just 4 percent of the total data taken by the experiment, with the full data analysis expected to take another year to complete.

    vast
    Q-weak at Jefferson Lab has measured the proton’s weak charge. No image credit.

    The weak force is one of the four fundamental forces in our universe, along with gravity, electromagnetism and the strong force. Although the weak force acts only on the sub-atomic level, we can see its effects in our everyday world. The weak force plays a key role in the nuclear reaction processes that take place in stars and is responsible for much of the natural radiation present in our universe.

    The Q-weak experiment was designed by an international group of nuclear physicists who came together more than a decade ago to propose a new measurement at Jefferson Lab. They proposed the world’s first direct measurement of the proton’s weak charge, denoted by the symbol “qyw” represents the strength of the weak force’s pull on the proton, a measure of how strongly a proton interacts via the weak force. Since the weak charge of the proton is precisely predicted by the Standard Model, which is a well-tested theoretical framework that describes the elementary particles and the details of how they interact, it is an ideal parameter to measure experimentally as a test of the Standard Model.

    See the full article here, and there is much more.

    Thomas Jefferson National Accelerator Facility is managed by Jefferson Science Associates, LLC for the U.S. Department of Energy


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  • richardmitnick 2:29 pm on July 25, 2013 Permalink | Reply
    Tags: , , Jefferson National Accelerator Lab,   

    From Energy.gov- “Photo of the Week: Faster than the Speed of Light” 

    ENERGYDOTGOVE BANNER

    July 24, 2013
    Sarah Gerrity

    “If you’ve ever heard the thunderous sound of a sonic boom, you’ve experienced the shock waves in the air created by an object traveling faster than the speed of sound. But what happens when an object travels faster than the speed of light?

    disc
    Photo courtesy of Jefferson Laboratory.

    At Jefferson Laboratory, construction is underway to upgrade the Continuous Electron Beam Accelerator Facility (CEBAF) and the CEABF Large Acceptance Spectrometer (CLAS12) at Hall B. During the experiments, the accelerator will shoot electrons at speeds faster than the speed of light, creating shock waves that emit a blue light, known as Cherenkov light — this light is equivalent to the sonic boom. By recording data from Cherenkov light, scientists will be able to map a nucleon’s three-dimensional spin. The device will use 48 ellipsoidal mirrors assembled into one circular, 8-foot diameter mirror to capture this light. Pictured here is the web-like component that will support the mirrors in the accelerator itself.

    See the full article here.


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  • richardmitnick 9:43 am on April 5, 2013 Permalink | Reply
    Tags: , , Jefferson National Accelerator Lab, ,   

    From JLab via DOE Pulse: “Quarks’ spins dictate their location in the proton” 

    pulse

    Jefferson Lab

    “A successful measurement of the distribution of quarks that make up protons conducted at DOE’s Jefferson Lab has found that a quark’s spin can predict its general location inside the proton. Quarks with spin pointed in the up direction will congregate in the left half of the proton, while down-spinning quarks hang out on the right. The research also confirms that scientists are on track to the first-ever three-dimensional inside view of the proton.

    proton
    The quark structure of the proton. (The color assignment of individual quarks is not important, only that all three colors are present.)

    The proton lies at the heart of every atom that builds our visible universe, yet scientists are still struggling to obtain a detailed picture of how it is composed of its primary building blocks: quarks and gluons. Too small to see with ordinary microscopes, protons and their quarks and gluons are instead illuminated by particle accelerators. At Jefferson Lab, the CEBAF accelerator directs a stream of electrons into protons, and huge detectors then collect information about how the particles interact.

    cebaf

    According to Harut Avakian, a Jefferson Lab staff scientist, these observations have so far revealed important basic information on the proton’s structure, such as the number of quarks and their momentum distribution. This information comes from scattering experiments that detect only whether a quark was hit but do not measure the particles produced from interacting quarks.

    ‘If you sum the momenta of those quarks, it can be compared to the momentum of the proton. What scientists were doing these last 40 years, they were investigating the momentum distribution of quarks along the direction in which the electron looks at it – a one-dimensional picture of the proton,’ he explains.

    Now, he and his colleagues have used a new experimental method that can potentially produce a full three-dimensional view of the proton.”

    See the full article here.

    DOE Pulse highlights work being done at the Department of Energy’s national laboratories. DOE’s laboratories house world-class facilities where more than 30,000 scientists and engineers perform cutting-edge research spanning DOE’s science, energy, National security and environmental quality missions. DOE Pulse is distributed twice each month.

    DOE Banner


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  • richardmitnick 9:31 pm on January 18, 2013 Permalink | Reply
    Tags: , , Jefferson National Accelerator Lab   

    From D.O.E. Pulse: “Jefferson Lab engineers help space chamber reach cold target at unprecedented efficiency” 

    pulse

    January 21, 2013

    “As the U.S. sweated through its warmest year on record outside, a testing chamber at NASA Johnson Space Center in Houston reached its coldest temperatures yet on the inside, cooled by one of the world’s most efficient cryogenic refrigeration systems.

    chiller

    Designed by members of the Cryogenics group at the Department of Energy’s Jefferson Lab, the system reached its target temperature of 20 Kelvin, about -424 degrees F, for the first time in May 2012 and again during commissioning tests in late August. It reached its target temperature in just over a day and maintains a steady temperature with less than a tenth of a degree in variation over a load temperature range of 16 to 330 Kelvin, all with no loss of helium and using half the liquid nitrogen than comparable systems. But what is even more remarkable is its ability to maintain design efficiency down to a third of its maximum load.

    ‘The range of load temperature and capacity while maintaining peak efficiency and temperature stability is unprecedented, said Venkatarao (Rao) Ganni, deputy Cryogenics Department head, and a key member of the system design team.”

    See the full article here.

    DOE Pulse highlights work being done at the Department of Energy’s national laboratories. DOE’s laboratories house world-class facilities where more than 30,000 scientists and engineers perform cutting-edge research spanning DOE’s science, energy, National security and environmental quality missions. DOE Pulse is distributed twice each month.

    DOE Banner


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  • richardmitnick 10:02 am on March 27, 2012 Permalink | Reply
    Tags: , , Jefferson National Accelerator Lab,   

    From Jefferson Lab: “University of Regina completes milestone in major international physics project” 

    Researchers from the University of Regina and the Thomas Jefferson National Accelerator Facility (Jefferson Lab) in the United States, along with provincial and federal government representatives celebrated the completion of a significant milestone today in the international physics project called GlueX.

    Researchers in this experiment are looking to answer one of the most fundamental questions in science today: Why does matter stay together? University of Regina researchers have developed, constructed and recently delivered the largest and one of the most critical components of the project – the $9 million barrel calorimeter (BCAL), which will be installed in Jefferson Lab’s Hall D and used to study the interaction of quarks, the basic building blocks of matter, in the GlueX project.

    The United States Department of Energy (US DOE) has classified the GlueX project as a Discovery Potential experiment meaning that it has Nobel Prize-winning potential.

    i1
    One module of the 48 that were developed and constructed by approximately 60 researchers at the University of Regina. The entire system contains more than 750,000 optic fibers that channel light along their 3.9 meter length to detectors that amplify the light so it can be digitized and measured.

    See the full article here.

    Thomas Jefferson National Accelerator Facility is managed by Jefferson Science Associates, LLC for the U.S. Department of Energy

     
  • richardmitnick 9:40 pm on November 24, 2011 Permalink | Reply
    Tags: , , , , , , , , , INL, Jefferson National Accelerator Lab, , , , , , , , , , , , , , , , , , , , ,   

    Advocate for Basic Research at D.O.E. Labs and NASA After the Deficit Reduction Debacle in Washington 

    The recent deficit super committee debacle in Washington means possible debilitating budget cuts to your D.O.E labs and NASA missions. Please get ready to write, email, phone, your congressional representatives and senators. It’s your tax dollars, folks.

    Here’s what’s at risk:


    D.O.E.:


    Argonne


    Ames


    Berkeley


    Brookhaven


    Fermilab


    INL


    Jefferson


    Livermore


    Los Alamos


    NSCL


    Oak Ridge


    Pacific Northwest


    Princeton Plasma Physics


    Sandia


    SLAC

    US/LHC


    The many other aspects of the D.O.E. Office of Science


    NASA:


    Hubble (Yes, there is still a budget for Hubble)


    Fermi

    i2
    Goddard


    Chandra

    nh
    Herschel


    JPL

    nk
    Kepler

    nsofia
    SOFIA


    Spitzer


    Webb


    WISE

    All of the other missions, current and future.

    Everything is at risk. The U.S. future as a leader in basic scientific research is at risk. Remember the Superconducting Super Collider? Killed off in 1993 by the dimwitted (then Democrat dominated) Congress?

    The tax dollars are yours. Visit the D.O.E lab and NASA mission web sites. Look around. See if you think that these are worthy of your tax dollars.

    Read back through past entries in this blog, you will see that it is not all High Energy Physics, Astronomy, and rocket science. It is also Biology, Chemistry, Medicine, Genetics, Clean and Renewable Energy, Ecology, Climate, you name it, our great labs and NASA missions are there to help make our lives better.

     
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