Re-creating the Big Bang

1. Re-creating the Big Bang Experiments at the Large Hadron Collider Dr Cormac O’ Raifeartaigh (WIT)

2. Overview I What II Why III How IV A brief history V Beyond the Standard Model

3. A particle accelerator ‘Atom smasher’ Particles created Detected I The Large Hadron Collider LHC at CERN, Geneva

4. How High speed proton beams Opposite directions - collisions Huge energy of collision Create short-lived particles Detection and measurement

5. 27 km Energy: 14 TeV Low temp: 1.6 K Ultra high vacuum HOW

6. Explore fundamental constituents of matter Investigate forces that hold matter together Glimpse of early universe Highest energy since BB Why Are the forces of the universe related ?

7. Newton (1642-1727) Newton’s gravity • Planet orbits due to gravity • Gravity caused by sun’s mass • Terrestrial gravity due to earth’s mass

8. Democritus

9. Four forces of nature • Force of gravity Holds cosmos together Long range • Electromagnetic force Holds atoms together • Strong nuclear force: holds nucleus together • Weak nuclear force: radioactivity The atom

10. Atoms: chemistry • Democritus (600 BC): matter made of atoms • Dalton (19th ct): • Mendeleev (19th ct): chemical reactions

11. Atoms: physics • Maxwell (19th ct): atomic theory of gases • Einstein: (1905): Brownian motion due to atoms? • Perrin (1908): verified Brownian motion Perrin Einstein

12. The atomic nucleus • Most projectiles through • A few deflected backwards • Atom has nucleus • Electrons outside Rutherford (1911)

13. Nuclear model of the atom Atom • Nucleus (+ve): • Electrons (-ve): orbiting • Force: electromagnetic Nucleus • Protons (1909) • Nucleus (1911) • Neutrons (1932)? nNu Nuclear force: stronger than electromagnetic?

14. Splitting the nucleus Cockcroft and Walton: particle accelerator Particles used to split the nucleus (1932) He + Li = Nobel prize (1956)

15. Nuclear fission • Meitner, Hahn: nuclear fission • Huge energy released • Chain reaction • Nuclear bomb • Nuclear power • Nuclear power stations

16. New particles • Cosmic rays New particle accelerators cyclotron

17. Particle Zoo

18. 108 particles New periodic table Not fundamental Inner structure Symmetry arguments Quarks The quark model Murray Gellmann

19. Six different quarks (u,d,s,c,t,b) Six leptons (e,μ,τ, υe,υμ,υτ) Particles of matter: fermions Two extra generations Quarks and leptons

20. Matter: leptons and quarks Force carriers: bosons The Standard Model • EM + weak = electroweak • Stong force = quark force Higgs field Particle masses Higgs boson

21. Higgs boson 120-180 GeV Set by mass of top quark, Z boson LHC and the standard model

22. Unification of 3 forces Grand unified theory Supersymmetry Supersymmetric particles? Unification of 4 forces Theory of everything String theory Extra dimensions Beyond the standard model

23. LHC and cosmology √ 1. Exotic particles 2. Mini BB = photo of early U 3. Nature of dark matter? 4. Missing antimatter 5. Superforce

24. Higgs boson Close chapter on SM Supersymmetric particles Open chapter on unification WIMPS Explain Dark Matter Unexpected particles Revise theory low temperature 3. Summary: expectations

25. 20 member states 10 associate states Ireland not a member Epilogue: CERN Organization for Nuclear research No particle physics in Ireland