Overview of Particle Physics -- the path to the Standard Model

1. Overview of Particle Physics -- the path to the Standard Model

2. Topics • historical flashback over development of the field • “prehistory” 19th century • electron, radioactivity, nucleus • cosmic rays • spectroscopy era • collider era • standard model of particle physics

3. A Century of Particle Physics J.J Thomson Top quark 1995 Electron – 1897

4. Sizes and distance scales • visible light: wavelength ≈5∙10-7m • virus 10-7m • molecule 10-9m • atom 10-10m • nucleus 10-14m • nucleon 10-15m • quark <10-18m

5. The Building Blocks of a Dew Drop • dew drop: 1021 molecules of water. • Each molecule = one oxygen atom and two hydrogen atoms (H2O). • Atom: nucleus surrounded by electrons. • Electrons bound to the nucleus by photons • nucleus of a hydrogen atom = single proton. • Proton: three quarks, held together by gluons just as photons hold the electron to the nucleus in the atom   

6. Very early era (19th century) • chemistry, electromagnetism • discharge tubes, “canal rays”, “cathode rays” • photoelectric effect (Hertz, 1887) • radioactivity (Becquerel, 1895) • X-rays (Röntgen, 1895)

7. Atoms, Nucleus • electron: first hint that atom not indivisible • natural radioactivity  understanding of composition of atom, nucleus • atom = nucleus surrounded by electrons (Geiger, Marsden, Rutherford, 1906 -1911) • hydrogen nucleus = proton, is component of all nuclei (1920) • neutron (Bothe, Becker, Joliot-Curie, Chadwick, 1930 – 1932)

9. Cosmic rays • Discovered by Victor Hess (1912) • Observations on mountains and in balloon: intensity of cosmic radiation increases with height above surface of Earth – must come from “outer space” • Much of cosmic radiation from sun (rather low energy protons) • Very high energy radiation from outside solar system, but probably from within galaxy

11. Cosmic rays -- “elementary” particles • new detectors (cloud chambers, emulsions) exposed to cosmic rays  discovery of many new particles • positron (anti-electron) : predicted by Dirac (1928), discovered by Anderson 1932 • muon (μ): 1937 Nedermeyer • pion (π) predicted by Yukawa (1935), observed 1947 (Lattes, Occhialini, Powell) • strange particles (K, Λ, Σ,…..

12. Particle Zoo • 1940’s to 1960’s : • Plethora of new particles discovered (mainly in cosmic rays): • e-, p, n, ν, μ-, π±, π0, Λ0, Σ+ , Σ0 , Ξ,…. • question: • Can nature be so messy? • are all these particles really intrinsically different? • or can we recognize patterns or symmetries in their nature (charge, mass, flavor) or the way they behave (decays)?

13. The Particle Zoo! ±, 0, e, ±, K±, K0S, K0L, 0, p, n, +, 0, , , …

14. Particle spectroscopy era • 1950’s – 1960’s: accelerators, better detectors • even more new particles are found, many of them extremely short-lived (decay after 10-21 sec) • 1962: “eightfold way”, “flavor SU(3)” symmetry (Gell-Mann, Ne’eman) • allows classification of particles into “multiplets” • Mass formula relating masses of particles in same multiplet • quark model – three different kinds of quarks (u, d, s) • Allows prediction of new particle Ω- , with all of its properties (mass, spin, expected decay modes,..) • subsequent observation of Ω- with expected properties at BNL (1964)

15. Ω-BNL1964 • eight-fold way  quark model – particles made up of three different “quarks” – u, d, s • p = uud, n = udd,… Ω- = sss • refinement of these ideas, more quarks, “color”, gauge field theory  Standard Model http://www.bnl.gov/bnlweb/history/Omega-minus.asp

16. Standard Model • A theoretical model of interactions of elementary particles, based on quantum field theory • Symmetry: • SU(3) x SU(2) x U(1) • “Matter particles” • Quarks: up, down, charm,strange, top, bottom • Leptons: electron, muon, tau, neutrinos • “Force particles” • Gauge Bosons •  (electromagnetic force) • W, Z (weak, electromagnetic) • g gluons (strong force) • Higgs boson • spontaneous symmetry breaking of SU(2) • mass

17. Contemporary Physics Education Project

18. Particles of Standard Model Quarks Leptons +2/3 -1/3 -1 0 ne u u d d e u d I II III nm c c s s m c s BosonsFermions nt t b b t t t b g g g g g g g g g Z W±

19. “every-day” matter Proton Neutron d u u d u d Photon g Electron Electron Neutrino e ne

20. Electron Proton Electromagnetic interaction q1 Photon q2

21. Proton Neutron d u u d u d Electron Anti-electron Neutrino W - e ne Weak interaction Beta decay Mean lifetime of a free neutron ~ 10.3 minutes Mean lifetime of a free proton > 1031 years!

22. The Strong Force d u g Strong force caused by the exchange of gluons u d

23. Forces (interactions) • Strong interaction 1 • Binds protons and neutrons to form nuclei • Electromagnetic interaction 10-2 • Binds electrons and nuclei to form atoms • Binds atoms to form molecules etc. • Weak interaction 10-10 • Causes radioactivity • Gravitational interaction 10-39 • Binds matter on large scales

24. What holds the world together?

25. 1977 – 1992 Many null results 1992 – 1993 A few interesting events show up 1994, DØ mt > 131 GeV/c2 1994, CDF First evidence mt ~ 170GeV/c2 1995 – CDF, DØ Discovery! The Discovery of Top Quark

26. Creating Top Anti-Top Quark pairs

27. Artist’s impression of a top event

28. Muon Missing energy Electron What do we actually “see” Jet-1 Jet-2

29. - ® m + e jets t t “event display” of a DØ top event

30. Ωb (http://www.fnal.gov/pub/presspass/images/DZero-Omega-discovery.html • 2008 DØ experiment at Fermilab: • discover brother of Ω- , the Ωb • Ω- = sss, Ωb = ssb, • theory predicts properties, decay modes, .. • confirmed by experiment

31. Summary • we’ve come a long way …… • Standard Model (theory of particle interactions) works embarrassingly well! • Has been tested by many hundreds of precision measurements over last three decades – very few measurements differ by more than 1 or 2 standard deviations • Even some amount of frustration – always hope to see experimental result in disagreement with theory • But there are some open questions …………………