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1 The Large Hadron Collider Is Turning On (Again) In November Michael Shupe Department of Physics University of Arizona.

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Presentation on theme: "1 The Large Hadron Collider Is Turning On (Again) In November Michael Shupe Department of Physics University of Arizona."— Presentation transcript:

1 1 The Large Hadron Collider Is Turning On (Again) In November Michael Shupe Department of Physics University of Arizona

2 2 French/Swiss Countryside outside Geneva, Switzerland. Large Hadron Collider

3 3 3 At four points around the ring the two beams are brought together for head-on collisions. At four points around the ring the two beams are brought together for head-on collisions. The beams are actually composed of many bunches of protons, with bunch crossings (collisions) every 25 nanoseconds. The beams are actually composed of many bunches of protons, with bunch crossings (collisions) every 25 nanoseconds. At nominal energy, it takes 90 microseconds for a proton to make one revolution. At nominal energy, it takes 90 microseconds for a proton to make one revolution. 7 GeV 7 GeV

4 4 LHC experiments, and a few of the physicists…

5 5 The ATLAS Detector 7000 tons of detector sits 100m underground 150 million sensors incorporated into ATLAS

6 6 The ATLAS Detector One of four experiments at the LHC: 46m in length and 25m in diameter. 100 m underground.

7 7

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10 10 ATLAS By The Numbers Size Size ½ size of Notre Dame Cathedral ½ size of Notre Dame Cathedral Weighs as much as 100 747 airplanes Weighs as much as 100 747 airplanes Data Data 3200 terabytes expected 3200 terabytes expected Equivalent to 7km of CDs stacked vertically Equivalent to 7km of CDs stacked vertically Energy and Temperature Energy and Temperature 7 times the energy of any existing accelerator 7 times the energy of any existing accelerator 100,000 times hotter than the sun 100,000 times hotter than the sun Collaboration Collaboration 2500 physicists 2500 physicists 37 countries 37 countries 169 universities and laboratories 169 universities and laboratories

11 11 To study the fundamental building blocks of nature, and the interactions among them. Electromagnetic Force Strong (Nuclear) Force Weak Force (Changes particle types) Gravity (Gravitons?) What’s the LHC for?

12 12 LHC and the Big Bang At the LHC we will recreate temperatures similar to those found about one nanosecond after the Big Bang.

13 13 What Can Be Found at the LHC? Source of mass: find the Higgs particle? Source of mass: find the Higgs particle? Confirm new theories: Supersymmetry? Confirm new theories: Supersymmetry? Astrophysical phenomena: Dark Matter particles? Astrophysical phenomena: Dark Matter particles? More BTSM: Compositeness?, Extra Large Dimensions? More BTSM: Compositeness?, Extra Large Dimensions? Complete surprises? (See the history of this field.) Complete surprises? (See the history of this field.) Dennis Overbye

14 14 Mass puzzle, and the Higgs Particle. The standard model of particle physics works wonderfully well. The standard model of particle physics works wonderfully well. Unification of the Electromagnetic and Weak Forces. Unification of the Electromagnetic and Weak Forces. Form of the Strong Force. Form of the Strong Force. But it does not explain why particles have masses nor why some particles are very light while others are very massive. But it does not explain why particles have masses nor why some particles are very light while others are very massive. Providing mass to all massive particles is role of the predicted Higgs particle. We are searching for the Higgs at the LHC.

15 15 Finding a Higgs A Higgs, if it is produced at the LHC, will decay immediately into other lighter particles. A Higgs, if it is produced at the LHC, will decay immediately into other lighter particles. Such particles can be reconstructed in a detector (ATLAS, CMS). Such particles can be reconstructed in a detector (ATLAS, CMS). By searching for these “daughter” particles, one can reconstruct the Higgs. By searching for these “daughter” particles, one can reconstruct the Higgs. Many other decays can mimic a Higgs, producing background. Many other decays can mimic a Higgs, producing background. A few hundred Higgs events seen after a few years of running

16 16 Dark Matter From Newtonian mechanics we expect the rotational velocity of galaxies to drop off with radius. From Newtonian mechanics we expect the rotational velocity of galaxies to drop off with radius. Pluto’s orbit is about 250 times longer than Earth’s even though it’s only 40 times farther from the Sun. Pluto’s orbit is about 250 times longer than Earth’s even though it’s only 40 times farther from the Sun. Data show that velocities remain nearly constant. Data show that velocities remain nearly constant. Galaxies should fly apart. Galaxies should fly apart. Indication that all mass in galaxies is not contained in stars. Indication that all mass in galaxies is not contained in stars.

17 17 Dark Matter Candidates Weakly Interacting Massive Particles Weakly Interacting Massive Particles WIMPs WIMPs As yet undiscovered particle/particles As yet undiscovered particle/particles Only interacts via the weak force and gravity. Only interacts via the weak force and gravity. A leading WIMP candidate is the neutralino. A leading WIMP candidate is the neutralino. If this particle exists, it is likely to be found at the LHC. If this particle exists, it is likely to be found at the LHC.

18 18 This is one of the new-physics directions being pursued at Arizona: Leading an effort to search for a charged Higgs particle decaying into a chargino and neutralino. Leading an effort to search for a charged Higgs particle decaying into a chargino and neutralino. Definitive evidence for physics beyond the Standard Model. Definitive evidence for physics beyond the Standard Model. The neutralino may be the solution to the dark matter problem. The neutralino may be the solution to the dark matter problem. One of many scenarios for the decay of the Higgs particle. One of many scenarios for the decay of the Higgs particle.

19 19 The University of Arizona Team The University of Arizona Team Faculty Research Associates & Staff Students

20 20 The ATLAS Detector Arizona’s contributions to ATLAS. Arizona’s contributions to ATLAS. Forward Calorimeter Forward Calorimeter Forward Muon Chambers Forward Muon Chambers Radiation Studies Radiation Studies Development of Data Analysis Development of Data Analysis

21 21 LAr Calorimeters Arizona

22 22 Close-up photo of the front of one of the forward calorimeter modules during construction. One of the prototypes for this detector element is located in the hallway. Cutaway drawing of one FCal module. The LHC accelerator vacuum beam pipe passes through the hole in the middle of the module. Forward Calorimeter

23 23 Forward Calorimeter Construction in the Basement of Physics: Even Experimentalists Dress Up Occasionally

24 24 Forward Calorimeter Installation

25 25 Muon Detector Muons are the only charged particles which can pass through the calorimeters. The muon system detects such particles and can determine their charge and momentum.

26 26 CSC (Cathode Strip Chambers) CSCs

27 27 CSC Chambers

28 28 One of My Physics Interests: Quark Compositeness Are there smaller things inside quarks? Are there smaller things inside quarks? Recall Rutherford Scattering: excess events at large angles. Recall Rutherford Scattering: excess events at large angles. LHC analogy is quark collisions with large momentum transfer. Small scattering centers inside quarks would modify the p T distribution. (“Jets” simulation for ATLAS shown at right.) LHC analogy is quark collisions with large momentum transfer. Small scattering centers inside quarks would modify the p T distribution. (“Jets” simulation for ATLAS shown at right.)

29 29 One of My Service Contributions: ATLAS Backgrounds Simulation, and Shielding Design

30 30 Installation of bridge piece for ATLAS forward shield.

31 31 What next? Next beam in LHC: November Next beam in LHC: November First collisions: December. First collisions: December. First low energy data: Spring 2010 First low energy data: Spring 2010 Increase in rate & energy: 2010 – 2011 Increase in rate & energy: 2010 – 2011 First Discoveries in 2011… First Discoveries in 2011…

32 32 Summary The LHC turn on has just begun. The LHC turn on has just begun. World’s largest scientific experiment to date. World’s largest scientific experiment to date. Expect to find answers to many fundamental questions. Expect to find answers to many fundamental questions. Mass, Dark Matter, Supersymmetry, and More! Mass, Dark Matter, Supersymmetry, and More! The University of Arizona has played a significant role in developing and building this device. The University of Arizona has played a significant role in developing and building this device. Exciting times ahead… Exciting times ahead…

33 33 CSC Muon Chambers Resolution is 70 μm

34 34 CSC Calibration System Improves resolution Improves resolution Allows detector to operated in a high rate environment. Allows detector to operated in a high rate environment.

35 35 EM Calorimeter Barrel in cryostat Endcap

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