In neutrons and protons, quarks take wrong turns.Physicists peering inside the neutron are seeing glimmers of what appears to be an impossible situation. The vexing findings pertain to pertain to verb relate to, concern, refer to, regard, be part of, belong to, apply to, bear on, befit, be relevant to, be appropriate to, appertain to quarks Quarks The basic constituent particles of which elementary particles are understood to be composed. Theoretical models built on the quark concept have been very successful in understanding and predicting many phenomena in the physics of elementary particles. , which are the main components of neutrons and protons. The quarks, in essence, spin like tops, as do the neutrons and protons themselves. Now, experimenters at the Thomas Jefferson National Accelerator Facility Thomas Jefferson National Accelerator Facility (TJNAF), commonly called Jefferson Lab (JLAB), is a U.S. national laboratory operated as of 1 June 2006 by Jefferson Science Associates, LLC, a joint venture between Southeastern Universities Research Association, Inc. in Newport News Newport News, independent city (1990 pop. 170,045), SE Va., on the Virginia peninsula, at the mouth of the James River, off Hampton Roads, near Norfolk; inc. 1896. , Va., have found hints that a single quark quark (kwôrk): see elementary particles. quark Any of a group of subatomic particles thought to be among the fundamental constituents of matter—more specifically, of protons and neutrons. can briefly hog most of the energy residing in a neutron, yet spin in the direction opposite to that of the neutron itself. "That's very disturbing," comments theoretical physicist Xiangdong Ji of the University of Maryland University of Maryland can refer to:
The finding suggests that scientists may have erred in calculations using fundamental theory, to predict quark behavior within neutrons, he says. It might also indicate that orbital motions of particles within neutrons, in addition to those particles' spins, are more important than previously recognized. Those motions might be akin to the moon's rotation around Earth as the satellite also spins about its own axis. Given that neutrons and protons are sister particles, called nucleons, the new findings apply to both, says Xiaochao Zheng, a member of the experimental team who's now "Who's Now" was a daily series aired during SportsCenter throughout July 2007, in which viewers helped ESPN determine the ultimate sports star by considering both on-field success and off-field buzz. at Argonne (Ill.) National Laboratory. Nucleons are the building blocks of atomic nuclei. A typical nucleon nucleon, term applying to both the proton and the neutron, the two constituents of atomic nuclei. The nucleon may be considered a single particle, of which the proton and the neutron are two different states. See atom; elementary particles. includes three quarks: two down quarks and one up quark up quark n. Abbr. u A quark with a charge of + 2/3 and a mass about 607 times that of the electron. It is a component of protons and neutrons. See Table at subatomic particle. for a neutron; two up quarks and one down quark for a proton. In addition to those so-called valence Valence, city, France Valence (väläNs`), city (1990 pop. 65,026), capital of Drôme dept., SE France, in Dauphiné, on the Rhône River. quarks, each nucleon contains multitudes of gluons--particles that bind quarks --and of short-lived quark-antiquark pairs, known collectively as the quark sea. Each of these constituents of a nucleon carries some share of the nucleon's energy, although the distribution of that energy among the constituents constantly shifts, Ji explains. From previous experiments, scientists knew that only valence quarks can grab major portions of a nucleons total energy content, says Jian-Ping Chen of the Jefferson lab, a coleader of the experiment. The new spin-detecting experiment is the first to measure the state of the neutron when most of its energy momentarily resides in a single quark. Calculations based on the prevailing theory of quark behavior predict that any quark holding more than about half the energy of a nucleon should spin in the same direction as the nucleon. However, when the new experiment probed valence quarks temporarily laden with up to 60 percent of a neutron's energy, it revealed that only the up quarks behaved as expected. The down quarks somehow carried most of the energy yet rotated in a direction opposite to that of the neutron as a whole. Electrons and entire atoms also have spins. To arrive at the new findings, the experimenters made a target of helium gas in which nearly all atoms were forced to spin in the same direction and bombarded it with a beam of high-energy electrons, whose spins were also forced to have uniform orientations. The researchers determined the spin orientations of the quarks in the helium atoms by placing detectors in specific positions where they are more likely to make detections when the orientations of the electron's spin and the quark's spin are opposite, Zheng says. She and her colleagues present their results in an upcoming Physical Review Letters Physical Review Letters is one of the most prestigious journals in physics.[1] Since 1958, it has been published by the American Physical Society as an outgrowth of The Physical Review. . Since the late 1980s, experiments have revealed that no more than 20 to 30 percent of a nucleon's spin comes from the spin of its valence quarks. Physicists have been struggling to identify which of the nucleons other constituents contribute to nucleon spin and how much--a puzzle known as the proton-spin crisis (SN: 9/6/97, p. 158). These long-awaited neutron-spin data indicate that, under some conditions, the previously overlooked orbital motions of valence quarks make a major contribution to nucleon spin, comments theorist Gerald A. Miller of the University of Washington in Seattle. |
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