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What Are They Doing at Fermilab Lately? Don Lincoln Fermilab
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What’s the Point? High Energy Particle Physics is a study of the smallest pieces of matter. It investigates (among other things) the nature of the universe immediately after the Big Bang. It also explores physics at temperatures not common for the past 15 billion years (or so). It’s a lot of fun.
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Periodic Table u d u u d d Proton Neutron Electron Gluons hold quarks together Photons hold atoms together HeliumNeon All atoms are made of protons, neutrons and electrons
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All particles have ‘anti-particles’, which have similar properties, but opposite electrical charge Particles –u,c,t +2/3 –d,s,b -1/3 –e, , -1 Anti-particles –u,c,t -2/3 –d,s,b +1/3 –e, , +1
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Now (15 billion years) Stars form (1 billion years) Atoms form (300,000 years) Nuclei form (180 seconds) ??? (Before that) 4x10 -12 seconds Nucleons form (10 -10 seconds) Quarks differentiate (10 -34 seconds?)
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Fermi National Accelerator Laboratory (a.k.a. Fermilab) Begun in 1968 First beam 1972 (200, then 400 GeV) Upgrade 1983 (900 GeV) Upgrade 2001 (980 GeV) Jargon alert: 1 Giga Electron Volt (GeV) is 100,000 times more energy than the particle beam in your TV. If you made a beam the hard way, it would take 1,000,000,000 batteries
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Fermilab Facts Named after Enrico Fermi, the famous Italian physicist who worked on the Manhattan Project. Current Director: Pierre Odonne Fermilab encompasses 6800 acres, much of it used for prairie restoration and preserving open space in the western suburbs. Employees about 2000 people. Original cost $250,000,000. Approximately the same amount in upgrades over the last 30 years. Electric bill between $10,000,000 and $20,000,000 NO classified work is done here.
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Increasing ‘Violence’ of Collision Expected Number of Events Run II Run I Increased reach for discovery physics at highest masses Huge statistics for precision physics at low mass scales Formerly rare processes become high statistics processes 1 10 100 1000 The Main Injector upgrade was completed in 1999. The new accelerator increases the number of possible collisions per second by 10-20. DØ and CDF have undertaken massive upgrades to utilize the increased collision rate. Run II began March 2001
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How Do You Detect Collisions? Use one of two large multi-purpose particle detectors at Fermilab (DØ and CDF). They’re designed to record collisions of protons colliding with antiprotons at nearly the speed of light. They’re basically cameras. They let us look back in time.
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Ionization - - Before and During Passage After Passage
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Track through many detectors Detectors hit
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Showers: Energy Detection ee ee ee ee ee ee ee ee ee ee ee Number of Particles Energy per Particle 1 24816 And so on
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How Different Particles Interact with a Detector Shower Muon Electron Pion Photon Neutrino Calorimeter Ionization Detector
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Silicon Central Tracker Magnet Calorimeter Muon System Key Shower Ionization Neutral e Detector, End-On View
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DØ Detector: Run II 30’ 50’ Weighs 5000 tons Can inspect 3,000,000 collisions/second Will record 50 collisions/second Records approximately 10,000,000 bytes/second Will record 10 15 (1,000,000,000,000,000) bytes in the next run (1 PetaByte).
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Remarkable Photos This collision is the most violent ever recorded. It required that particles hit within 10 -19 m or 1/10,000 the size of a proton In this collision, a top and anti-top quark were created, helping establish their existence
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Calorimeters Tracker Muon System Beamline Shielding Electronics protons antiprotons 66 feet In Run II (March 1, 2001), the Fermilab Tevatron will deliver 10-20 times as many collisions per second as Run I. The DØ detector required an overhaul in order to cope.
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Eight cylinders covered with scintillating fiber are read out with a novel light detector (VLPCs). VLPCs DØ Fiber Tracker
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1.25 m p pp DØ Silicon Tracker 800,000 distinct detector elements Very complex (fragile) Absolutely crucial for viewing the details of how particles behave near the collision. Particles that don’t come from the collision point serve as ‘flags’ of interesting physics.
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DØ Muon System Muons provide a signature of many interesting physics events. Muons penetrate dense material for long distances. Thus muon detectors are outside the large amount of metal that makes the rest of the detector. The muon system consists of many different detector technologies, and is the physically largest system.
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Run II: What are we going to find? I don’t know! Improve top quark mass and measure decay modes. Do Run I more accurately Supersymmetry, Higgs, Technicolor, particles smaller than quarks, something unexpected?
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www-d0.fnal.gov/~lucifer/PowerPoint/Kulak_Sep2005.ppt
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