1. DISCOVERING THE QUANTUM UNIVERSE Jonathan Feng University of California, Irvine Physical Sciences Breakfast Lecture Series Beckman Center of the National Academies 28 November 2006

2. 28 Nov 06Feng 2 QUANTUM UNIVERSE? Quantum theory governs the very small (atoms). The Universe is very big. What do these have to do with each other? In fact, studies of the very small and the very big have become intimately related, and are the focus of an experimental program whose flagship is the Large Hadron Collider.

3. 28 Nov 06Feng 3 VERY SMALL: STATUS REPORT electron 10  10 meters (thickness of human hair ~ 10 -5 m) up quark down quark atom nucleus proton neutron 10  14 meters 10  15 meters < 10  8 meters

4. 28 Nov 06Feng 4 BASIC BUILDING BLOCKS Atoms Light Frederick Reines 1995 Nobel Prize for the Detection of the Neutrino

5. 28 Nov 06Feng 5 PUZZLES Periodic table is…periodic. All atom masses are integral multiples of proton/neutron masses. What about elementary particles? vs.

6. 28 Nov 06Feng 6 ELEMENTARY PARTICLE MASSES Mass proportional to area: Are these made of something else? Are there more quark-, neutrino-,and electron-like particles? top quark Z W... e   e  u d s c b photons gluons

7. 28 Nov 06Feng 7 THE HIGGS BOSON In fact, with only the known particles, the current theory is incomplete: it predicts that all particles are massless and travel at the speed of light. A hypothetical particle, the Higgs boson, beautifully fixes this problem, but we’ve yet to find it. h? electron top quark Normal particles bouncing off Higgs particles

8. 28 Nov 06Feng 8 VERY BIG: STATUS REPORT galactic cluster 10  meters solar systemgalaxy 10  meters 10  meters > 10  meters universe

9. 28 Nov 06Feng 9 COMPOSITION OF THE UNIVERSE

10. 28 Nov 06Feng 10 PUZZLES What is dark matter? It is required to understand why galaxies don’t fly apart, but it can’t be any of the known particles. h? vs.

11. 28 Nov 06Feng 11 EXTRA DIMENSIONS How many dimensions are there? a) 3 b) 4 c) 10 d) 11 e) none of the above

12. 28 Nov 06Feng 12 Edwin Hubble Hubble (1929): The universe is expanding

13. 28 Nov 06Feng 13 Small Dimensions The universe does not expand into space – space itself expands Extrapolating back, space was small – the Big Bang Other dimensions could exist but still be small. Some theories even require extra spatial dimensions. For example, string theory requires 6 more.

14. 28 Nov 06Feng 14 E = mc 2 Many of these questions involve hypothetical particles. How can we investigate them? Einstein: E = mc 2. Energy can be transformed into mass. To make new, heavy particles, simply smash together known particles at high energy.

15. 28 Nov 06Feng 15 PARTICLE COLLIDERS E. O. Lawrence’s Cyclotron (1930s) Livingston Plot: Moore’s Law for Particle Colliders

16. 28 Nov 06Feng 16 Large Hadron Collider 18 miles in circumference Operation begins in 2007

17. 28 Nov 06Feng 17 The Accelerator Two proton beams rotate in opposite directions 100 m underground in Geneva on the French-Swiss border. The beams collide at 4 interaction points, which are surrounded by detectors.

18. 28 Nov 06Feng 18

19. 28 Nov 06Feng 19 LHC Detectors

20. 28 Nov 06Feng 20 UCI Faculty Working on the LHC TheoristsExperimentalists Jonathan FengArvind Rajaraman Yuri Shirman Mu-Chun Chen Andy Lankford Daniel Whiteson Anyes Taffard

21. 28 Nov 06Feng 21 UCI @ ATLAS The main UCI experimental responsibilities are in triggering and data acquisition. Data acquisition: the data collected by each detector is –1 Terabyte/second –10,000 Encyclopedia Britannicas/second –10 Libraries of Congress/minute –3 300GB hard drives/second –100 full length DVD movies/second –10,000 times the rate your computer can store data

22. 28 Nov 06Feng 22 UCI @ ATLAS Triggering: finding needles in haystacks D. Akerib

23. 28 Nov 06Feng 23 LHC AS MICROSCOPE High beam energies  short wavelengths. The LHC will provide extremely high resolution to probe substructure. Quark seen by the LHC (high resolution) Quark seen by current colliders (low resolution)

24. 28 Nov 06Feng 24 LHC AS HIGGS HUNTER The LHC will discover the Higgs boson – if it’s there!

25. 28 Nov 06Feng 25 LHC AS TIME MACHINE Cosmology (current) Cosmology (~2010) LHC Dark Matter Particle’s Mass (GeV) Deviation from Observed Dark Matter Density (%) The LHC will produce energies last seen 1 picosecond (10 -12 s) after the Big Bang, and may produce dark matter particles.

26. 28 Nov 06Feng 26 LHC SOCIOLOGY In each experiment, ~2000 collaborators from ~40 countries (and growing) The procedure for sharing data and credit is not completely clear and is a topic of heated debate

27. 28 Nov 06Feng 27 ACKNOWLEDGMENTS HEPAP Subpanel colleagues Available at registration desk and at http://interactions.org/quantumuniverse/qu2006/