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Anatomy of Accelerators

Anatomy of Accelerators. Marty Peters Summer 2006. Linear Accelerators. The 3 km long linear accelerator at Stanford. Photo: Stanford Linear Accelerator Center. Source: http://nobelprize.org/physics. Fermi National Accelerator Laboratory.

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Anatomy of Accelerators

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  1. Anatomy of Accelerators Marty Peters Summer 2006

  2. Linear Accelerators The 3 km long linear accelerator at Stanford.Photo: Stanford Linear Accelerator Center Source: http://nobelprize.org/physics

  3. Fermi National Accelerator Laboratory • Fermilab is home to the Tevatron, the world's highest-energy particle accelerator.Four miles in circumference, the Tevatron is housed in a tunnel about 30 feet below the big ring you see in this aerial view of the laboratory. A series of accelerators is used to send particles racing around the Tevatron at 99.9999 percent of the speed of light in a vacuum. The particles complete the four-mile course nearly 50 thousand times a second. Source: www.fnal.gov

  4. Two kinds of particles, protons and antiprotons, are sent around the ring in opposite directions. At two points in the ring, streams of these particles (called "beams") are steered right into each other, and collisions, at the rate of almost two million each second, are watched. Computer view of proton-antiproton collision. Source: www.fnal.gov, http://quarknet.fnal.gov

  5. Antiproton Production • To make antiprotons, protons are accelerated to 120 billion electron-volts (120 GeV) and strike them against a solid target. Out of the target come both antiprotons and secondary protons. There are about five secondary protons to each antiproton. • The system gets about 50 million antiprotons per shot off the target. Source: www.highbeam.com

  6. Antiprotons were produced by operating the Main Ring at 120 GeV. The antiprotons were collected in a Debuncher ring before they were transferred to the Accumulator where stochastic cooling was applied. After cooling, the antiprotons were injected into the Main Ring and Tevatron for acceleration to 1 TeV. With the recent extension of the Fermilab complex, the main Ring has been replaced by a new rapid cycling 120 GeV synchrotron, the Main Injector. In the same tunnel, an 8 GeV storage ring, the Recycler, has been constructed using permanent magnets. The Recycler acts as a repository for cooled antiprotons, thus permitting a high rate of cooling in the Accumulator which works best with low currents, to be maintained. The Recycler also receives antiprotons left over and decelerated after completion of a storage in the Tevatron. Stochastic cooling, initially installed in the Recycler, will be enhanced by the addition of electron cooling in the near future. Source: /nobelprize.org/physics

  7. In a single head-on collision between proton and antiproton in the Tevatron, hundreds of new particles are usually created. According to Einstein’s formula E=mc2, the maximum mass that can be converted from kinetic energy corresponds to the mass of about 2000 protons, if all the kinetic energy of the proton and antiproton in a single collision were to be converted to mass. Source: /nobelprize.org/physics

  8. DZero Collider Detector • Fermilab's two collider detectors--CDF and DZero--are about four stories high and weigh some 5,000 tons (10 million pounds) each. The particle collisions occur in the center of the detectors, which are crammed with electronic instrumentation. Source: www.fnal.gov

  9. Source: http://quarknet.fnal.gov Source: http://quarknet.fnal.gov

  10. Source: http://quarknet.fnal.gov

  11. CDF Collider Detector • Each detector has about one million individual pathways for recording electronic data generated by the particle collisions. The signals are carried over nearly a thousand miles of wires and cables--each one connected by hand and tested individually. Source: www.fnal.gov

  12. Schematic of Modern Detector Source: particleadventure.org

  13. Interaction of Particles with Detector Components Source: particleadventure.org

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