E (14 trillion electron-volts) = m (?) [c (close to the speed light).sup.2]: this fall, the massive Large Hadron Collider beneath France and Switzerland will switch on. Protons moving at almost the speed of light will collide with energies high enough, physicists hope, to solve matter's biggest mysteries.[ILLUSTRATION OMITTED] The hammering has stopped, the whining of power tools has abated. Only the hum of electronic detectors reverberates through the cavernous, eight-story space below the Swiss-Franco border that is stuffed with 9,300 magnets and enough niobium-titanium wire to stretch to the sun and back five times. But by September, if all goes according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. plan, two narrow beams of protons moving in opposite directions will begin making laps around the underground laboratory's 27-kilometer-long subatomic subatomic /sub·atom·ic/ (-ah-tom´ik) of or pertaining to the constituent parts of an atom. sub·a·tom·ic adj. 1. Of or relating to the constituents of the atom. 2. racetrack. The protons will pass from Switzerland to France without benefit of a passport, and smash into one another up to 500 million times a second. The most violent of those collisions will generate the heat, energy and densities that existed just a trillionth tril·lionth n. 1. The ordinal number matching the number one trillion in a series. 2. One of a trillion equal parts. tril of a second after the Big Bang big bang Model of the origin of the universe, which holds that it emerged from a state of extremely high temperature and density in an explosive expansion 10 billion–15 billion years ago. . And like a movie in perpetual rewind, these primordial re-creations will repeat about once a second. This is the Large Hadron Collider This article or section contains information about an expected future scientific facility. It is likely to contain information of a speculative nature and the content may change as the facility approaches completion. , or LHC LHC Large Hadron Collider LHC Lahore High Court LHC Lonely Hearts Club LHC Lake Havasu City (Arizona, USA) LHC Log Homes Council LHC Left-Hand Circular LHC Les Horribles Cernettes (band) , the mammoth atom smasher atom smasher: see particle accelerator. operated by the European Organization for Nuclear Research European Organization for Nuclear Research: see CERN. , better known by its French acronym, CERN CERN or European Organization for Nuclear Research, nuclear and particle physics research center straddling the French-Swiss border W of Geneva, Switzerland. . More than 15 years in the making, everything about the LHC is enormous, from the energies it generates--14 trillion electronvolts--to the nearly 60 metric tons of liquid helium Liquid helium required to cool its magnets, to the 20,000 tons of metal it houses and to the staff of thousands of scientists involved. All this just to study the tiniest particles in the universe. But more than the $8 billion price tag is riding on the LHC. Depending on what's detected, physicists may find out if they understand the fundamental building blocks of nature, or if "everything that physicists have been talking about for 45 years is wrong," says CERN theoretical physicist John Ellis. More parochially, the success of the LHC may vault Europe over the United States as the champion in physics research. The United States once had plans to build an even more powerful--and more costly- accelerator, the Superconducting Super Collider The Superconducting Super Collider (SSC) was a ring particle accelerator which was planned to be built in the area around Waxahachie, Texas. , but that project was scrapped when Congress eliminated funding 15 years ago. As revealed in Einstein's famous equation, E = [mc.sup.2], the enormous energies generated at the LHC will translate into large masses--and, particle physicists hope, a cornucopia cornucopia (kôr'ny  kō`pēə), in Greek mythology, magnificent horn that filled itself with whatever meat or drink its owner requested. of subatomic
particles never before seen. Many are betting that they will see
evidence of the elusive Higgs boson boson: see elementary particles; Bose-Einstein statistics. boson Subatomic particle with integral spin that is governed by Bose-Einstein statistics. , a hypothetical particle first proposed in the 1960s that could help explain why some elementary particles have mass. Finding the Higgs would be the crowning achievement for what physicists call the standard model, a highly successful theory that unifies three of the four known forces in nature and groups the fundamental constituents of matter into two broad categories. But researchers are hoping for more than a confirmation of the standard model. "I'm certainly not going to yawn if they find a Higgs boson; we'll break out the champagne and won't answer the phones for a week," Ellis says. "But that's somehow an expected discovery." Physicists hope the LHC will lead them beyond the standard model--to signs of extra dimensions, curled up into volumes of space so tiny they're barely detectable; and to rapidly evaporating, microscopic black holes that the accelerator might forge. And if scientists are really lucky, Ellis says, the experiments at LHC might double the scientists' pleasure, revealing a whole new set of elementary particles. According to a theory known as supersymmetry Supersymmetry A conjectured enhanced symmetry of the laws of nature that would relate two fundamental observed classes of particles, bosons and fermions. , every particle in nature has a heavier partnerwhose spin differs by a half integer. Supersymmetry would unite two seemingly disparate groups of particles. On one side of the divide are the bosons, the particles that act as messengers for the four fundamental forces in nature. These include the photon, which communicates the electromagnetic force; the W and Z, which mediate the weak nuclear interaction; and the gluon gluon, an elementary particle that mediates, or carries, the strong, or nuclear, force. In quantum chromodynamics (QCD), the quantum field theory of strong interactions, the interaction of quarks (to form protons, neutrons, and other elementary particles) is , which transmits the strong nuclear force. On the other side stand the fermions, the particles that react to those forces--electrons, quarks and the like. Supersymmetry says that the two groups belong under the same umbrella, residing in one big happy family. Moreover, the lightest supersymmetric particle In particle physics, the Lightest Supersymmetric Particle (LSP) is the generic name given to the lightest of the additional hypothetical particles found in supersymmetric models. In models with R-parity conservation, the LSP is stable. , called the neutralino, could be a candidate for dark matter, the long-sought, invisible material that astronomers say must exist to keep galaxies intact and galaxy clusters from flying apart. There simply isn't enough ordinary visible matter to provide the requisite gravitational grav·i·ta·tion n. 1. Physics a. The natural phenomenon of attraction between physical objects with mass or energy. b. The act or process of moving under the influence of this attraction. 2. glue. The dark matter particles would provide the extra tug and account for more than 80 percent of the mass of the universe. "That would be the fantastic breakthrough--that we would finally know what most of the matter in the universe is," says physics Nobel laureate Steven Weinberg of the University of Texas at Austin “University of Texas” redirects here. For other system schools, see University of Texas System. The University of Texas at Austin (often referred to as The University of Texas, UT Austin, UT, or Texas . "I don't think there's anything more exciting likely to come out of the LHC." Meeting the experiments Inside the LHC tunnel, the twin, hair-thin proton beams rev up to speeds approaching that of light. Steering them around the racetrack are 1,232 dipole magnets. Each magnet weighs 35 metric tons and is supercooled to 1.9 degrees Celsius above absolute zero. For most of their journey around the ring, the beams travel in separate vacuum pipes, but at four points they collide. These are the hearts of the main experiments, known by their acronyms: ALICE (A Large Ion Collider Experiment ALICE (A Large Ion Collider Experiment) is one of the six detector experiments being constructed at the Large Hadron Collider at CERN. It is optimized to study heavy ion collisions. Pb-Pb nuclei collisions will be studied at a centre of mass energy of 5.5 TeV per nucleon. ), ATLAS (A Toroidal LHC Apparatus), CMS (1) See content management system and color management system. (2) (Conversational Monitor System) Software that provides interactive communications for IBM's VM operating system. (Compact Muon Solenoid Coordinates: The Compact Muon Solenoid (CMS) experiment is one of two large general-purpose particle physics detectors being (as of 2007) built on the proton-proton Large Hadron Collider (LHC) at CERN in Switzerland. ) and LHCb (Large Hadron Collider beauty). ATLAS and CMS, the largest, are the major players. Both ATLAS and CMS fully enclose the portals where collisions happen, leaving no gaps for particles to escape without detection. Although they can't flee, many of the particles rapidly decay into a spray of other, more stable members of the subatomic zoo. Like CSI CSI Crime Scene Investigator CSI CompuServe, Inc. CSI Commodity Systems, Inc. CSI Commodity Systems Inc. (Boca Raton, FL) CSI Crime Scene Investigation (CBS TV show) CSI Christian Schools International detectives, scientists will measure the energy, mass and paths of those final particles to find out what happened in the collisions. The cores of ATLAS and CMS--the parts closest to the collision sites--contain particle trackers made of silicon wafers. Charged particles traveling through the wafers create electrical signals that reveal their passage. The CMS experiment alone has enough wafers to tile an 8-meter-deep Olympic-sized swimming pool. Just outside the wafers lie calorimeters, devices that slow down and absorb particles in order to measure their energies. Muons, the heavy cousins of electrons, are an especially precious commodity because they are both easy to detect and would be produced as end products in any reactions involving the Higgs boson. Both CMS and ATLAS have powerful magnets that curve the paths of charged particles. The amount of curvature reveals the particles' momentum and charge, allowing researchers to identify which charged particles are created directly or as a by-product by·prod·uct or by-prod·uct n. 1. Something produced in the making of something else. 2. A secondary result; a side effect. by-product Noun 1. of the collisions. CMS' magnet is in the shape of a solenoid solenoid (sō`lənoid'), device made of a long wire that has been wound many times into a tightly packed coil; it has the shape of a long cylinder. , a cylindrical coil of superconducting wire that generates a field 100,000 times stronger than that of Earth (measured at the surface). The field is confined by a steel clamp or yoke, which accounts for the bulk of the detector's 12,500 tons. [ILLUSTRATION OMITTED] In contrast, ATLAS uses a doughnut-shaped magnetic system, consisting of a ring of eight super cooled coils. The design requires no yoke and allows ATLAS to be eight times the size of CMS--46 meters long and 25 meters high--yet only half the weight, notes Fabiola Gianotti, an ATLAS researcher at CERN. Though searching for the same particles, the two mammoth experiments are independent. CMS, located beneath France, has better precision for measuring muons and electrons, while ATLAS, located beneath Switzerland, excels at detecting the shower of elementary particles created when quarks fragment, Gianotti says. Together, quarks and gluons Gluons The hypothetical force particles believed to bind quarks into “elementary” particles. Although theoretical models in which the strong interactions of quarks are mediated by gluons have been successful in predicting, interpreting, and , the particles that bind quarks together, are the elementary constituents of particles such as the proton. And in some sense, it's not the protons that really collide in the LHC, but the quarks and gluons they contain. "What we measure is not the individual quarks or gluons but the results of their [breakup], as they decay into other particles," Gianotti says. Evidence for extra dimensions Both ATLAS and CMS will also explore the ghostly realm of hidden dimensions. Particle physicists tend to think of subatomic particles as point masses, but string theory attempts to unify all forces and particles by viewing them as different vibrations of strands or loops called superstrings. Although the superstrings are probably too tiny to observe directly, the theory makes several predictions, including the existence of seven hidden dimensions of space. These dimensions would be tightly compacted or curled up. But through the production of new particles that might move or wind around these extra dimensions, ATLAS and CMS experiments will have the sensitivity to detect extra dimensions one-ten-billionth the size of an atom. If this theory of extra dimensions is correct, the LHC could become a factory for making microscopic black holes. In Einstein's theory of gravity Noun 1. theory of gravity - (physics) the theory that any two particles of matter attract one another with a force directly proportional to the product of their masses and inversely proportional to the square of the distance between them , which assumes a universe confined to three space dimensions and one of time, black holes could be generated by an accelerator much bigger than Earth. But in an alternative theory, gravity leaks out into other, unseen dimensions--a possible explanation of why gravity appears to be so much weaker than the other forces in nature. In this scenario, gravity is weak only if observed at long distances because the extra, hidden dimensions dilute its strength. Conversely, at the high energies and small scales probed by the LHC, gravity would become much stronger than it is in ordinary three-dimensional space, cramming enough matter together to form microscopic black holes as often as once a second. Such black holes, according to research by Stephen Hawking in the 1970s, ought to rapidly radiate ra·di·ate v. 1. To spread out in all directions from a center. 2. To emit or be emitted as radiation. ra away their energy and evaporate in an instant, and would not be dangerous. As they nearly instantaneously evaporate, they would radiate distinctive sprays of elementary particles, which stand out in the LHC detectors. The possibility of creating tiny black holes at the LHC is "quite a long shot," admits Steve Giddings of the University of California, Santa Barbara History The predecessor to UCSB, Santa Barbara State College, focused on teacher training, industrial arts, home economics, and foreign languages. Intense lobbying by an interest group in the City of Santa Barbara led by Thomas Storke and Pearl Chase persuaded the State . But he's hoping that long shot comes through. "Not only would we learn things about gravity and the fabric of spacetime," he says, "but we would apparently have direct evidence for extra dimensions of space." Getting fundamental Two medium-sized experiments get to the heart of other fundamental questions about the universe. Physicists analyzing data from the LHCb will try to gain insight about why the universe has so much more matter than antimatter antimatter: see antiparticle. antimatter Substance composed of elementary particles having the mass and electric charge of ordinary matter (such as electrons and protons) but for which the charge and related magnetic properties are opposite in sign. . Theory suggests that the cosmos began with equal amounts of both. But if matter and antimatter were mirror copies of each other, they would have annihilated, leaving behind only pure energy. Fortunately, an imbalance arose, allowing the tapestry of galaxies, the solar system and our own planet to coalesce co·a·lesce intr.v. co·a·lesced, co·a·lesc·ing, co·a·lesc·es 1. To grow together; fuse. 2. To come together so as to form one whole; unite: . LHCb examines the decay of B mesons This is a list of mesons; it is not comprehensive.this is a stub Particle Symbol Anti- particle Quark Makeup Spin and parity Rest mass MeV/c² S C B Mean lifetime s Principal decays Notes Charged Pion , particles composed of a specific pairing of a quark and antiquark--the bottom antiquark an·ti·quark n. The antiparticle of a quark. antiquark The antiparticle that corresponds to a quark. Noun 1. and either an up or a down quark. To catch the quarks, LHCb uses a 20-meter-long stack of detectors on a movable track that can intercept the spray of particles created during collisions. Studying how these quarks decay may reveal subtle differences between matter and antimatter. Rather than behaving as exact replicas of each other, the particles and antiparticles may exhibit slight distortions, akin to staring at a reflection in a wavy mirror. ALICE will concentrate on a unique state of matter that existed just after the birth of the universe by studying collisions between lead nuclei. Lead atoms are first stripped of some of their electrons, creating positively charged ions. Those heavy ions are then accelerated to nearly the speed of light and forced to collide nearly head-on within the LHC, briefly creating hot, dense fireballs. Within the fireballs, the neutrons and protons that make up the lead nucleus melt away, freeing quarks from their bonds with gluons. For a few precious moments, they form a new state of matter called the quark-gluon plasma. In previous experiments at both CERN and Brookhaven National Laboratory Brookhaven National Laboratory, scientific research center, at Upton (town of Brookhaven), Long Island, N.Y. It was founded in 1947 by Associated Universities, a management corporation sponsored by nine eastern U.S. universities. in Upton, N.Y., scientists have caught glimpses of this plasma. But the ALICE experiment, operating at higher energies, should look in greater detail at the types and abundance of particles generated as the plasma cools. ALICE researchers hope to gain insight into how the universe created the cosmic zoo of particles immediately following the hot Big Bang. All about the Higgs Finding the Higgs is the driving force behind much of the research at the LHC. According to the simplest version of the standard model, every particle in the universe ought to be massless. Electrons, for instance, ought to weigh exactly the same as photons, the particles of light--absolutely nothing. That, of course, is not the case. In the early 1960s, physicist Peter Higgs proposed that a hypothetical field, now called the Higgs field, permeates the universe like a cosmic vat of molasses molasses, sugar byproduct, the brownish liquid residue left after heat crystallization of sucrose (commercial sugar) in the process of refining. Molasses contains chiefly the uncrystallizable sugars as well as some remnant sucrose. . Many particles--but not all-would slow down as they propagated through the goo. Slowing down is a critical step. That's because Einstein's theory of relativity theory of relativity Einstein’s contribution to the space-time relationship. [Science: NCE, 843–844] See : Turning Point draws a sharp distinction between particles that have mass and those that don't. Massless particles move at the speed of light, while massive particles never reach that ultimate of all speeds. So slowing down, according to relativity theory, is tantamount to acquiring mass. Electrons, protons, neutrons and the like bulked up because the Higgs field slowed them down, while photons somehow remained immune to the molasses and stayed weightless. The Higgs field cannot be directly measured, but high-energy collisions like the ones possible at the LHC could excite the field. The decay of the Higgs boson would be the measurable signpost of that excitation. Theory suggests that the Higgs ought to lie in the mass-energy range that can be achieved at the LHC, Weinberg says. "The Higgs boson is not a slam dunk, but it is something that is expected, and it's really important for the future of fundamental physics to see whether in fact it's found," he says. But, Weinberg adds, "the greatest fear, I think, that the particle physics community has is that the LHC will find the Higgs boson and not find anything else. Because if that happens, we will simply have verified what is now the popular version of the standard model, and we won't have any experimental clues as to how to go beyond the model." If the Higgs particle has a mass at the high end of its predicted range, about 115 billion to 200 billion electronvolts, it should be easily detected, its decay products standing out dramatically against the background of particle debris from other processes. But if the particle tips the scales at the lighter end, the signal will be trickier to discern, Weinberg says. If the detection of the Higgs involves finding an extra, unaccounted-for signal in the collision debris, finding a supersymmetric particle requires finding a deficit. The lightest supersymmetric particle is thought to have no charge and to interact only weakly, which is why it is a candidate for the invisible dark matter. "As such, these particles would not be seen in a detector, hence the energy it carries would be missed," notes Ellis. It's like the curious incident of the dog that did nothing in the nighttime, from the Sherlock Holmes story, he notes. It's what's missing that counts. Whatever happens, says Weinberg, particle physics is about to awaken from some 30 years of slumber. Come September, the fun begins. Explore more * News from LHC. Visit Ihc.web.cern.ch/ lhc/News.htm LHC: The Inside View The Large Hadron Collider is just that: large, as shown by the illustration above. In it, protons (which are in the hadron hadron Any of the subatomic particles that are built from quarks and thus interact via the strong force. The hadrons fall into two groups: mesons and baryons. Except for protons and neutrons, which are bound in nuclei, all hadrons have short lives and are produced in category of particles) will collide at speeds nearing that of light. Each of four main laboratories along the 27-kilometer LHC tunnel is designed to detect different outcomes of the high-energy collisions. The ATLAS laboratory, illustrated lower left with drawings of people for scale, surrounds the tunnel and is almost half as long as the collider col`lid´er n. 1. (Physics) a [ILLUSTRATION OMITTED] Particle Zoo Standard Model of Particle Physics The standard model groups particles in two categories: particles that carry force and particles that make up matter. Each particle also has an antiparticle antiparticle, elementary particle corresponding to an ordinary particle such as the proton, neutron, or electron, but having the opposite electrical charge and magnetic moment. , such as an antiquark. Atomic nuclei are made of protons and neutrons, which in turn are made of quarks. Supersymmetry Supersymmetric particles--heavier companions for known particles--are theorized and not yet detected. They are likely candidates for dark matter, which is thought to make up most of the matter in the universe. Particles that transmit forces PARTICLE Force it carries photon electromagnetic W, Z vector bosons weak gluon strong graviton Graviton A theoretically deduced particle postulated as the quantum of the gravitational field. According to Einstein's theory of general relativity, accelerated masses (or other distributions of energy) should emit gravitational waves, just as accelerated gravity photino wino, zinc gluino gravitino grav·i·ti·no n. A hypothetical particle postulated in supersymmetry theory to be the fermion related to the graviton. [gravit(on) + (neutr)ino. Particles that make up matter [ILLUSTRATION OMITTED] Higgs Boson One tenet of the standard model is that no particle should have mass--observations show otherwise. Showing the existence of the Higgs boson would resolve this contradiction. The ATLAS experiment is tuned to detect the Higgs (a Higgs event is simulated at right). Confirming that the Higgs exists would solidify the standard model. [ILLUSTRATIONS OMITTED] |
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