1. Particle Physics and the LHC Pete Edwards Department of Physics, Durham University

2. What is matter?

3. In Aristotle’s philosophy there were four elements The concept of elements In 1808 Dalton listed many elements we recognise today

4. The periodic table In 1860’s Mendeleev arranged the elements by property into the periodic table

5. The periodic table Not only was this a beautiful pattern it was also predictive Some elements were missing and their properties could be predicted All were later discovered

6. Turn of the 20 th century Thus by the end of the 19th century the idea of elements was well developed The smallest piece of an element was known as an atom with atoms imagined as small spheres All matter in the Universe could be described by around 100 different atoms – not too bad!

7. Enter the electron In 1897 J J Thompson discovered the electron It soon became clear that it not only played an important role in electricity but was also contained inside atoms Atoms have sub-structure!

8. The plum pudding model One of the first models of the atom to include electrons Thompson imagined the electrons, with their negative charge, were stuck in a blob of positively charged material

9. The structure of atoms In 1912 the first particle physics experiment was carried out Fired radioactive particles at gold foil Found most of the particles went straight through But occasionally some did scatter back….. This was totally unexpected!

10. Rutherford scattering This showed that the atom has a dense positively charged nucleus surrounded by a cloud of electrons Rutherford said “It was if someone had told me that having fired a pistol at a sheet of paper, the bullet had bounced back!” The plum pudding model predicts that the average electric field is zero – no scattering The dense positively charged nucleus leads to scattering from a ‘point like’ object whose size could be worked out

11. A new picture of matter So in the 1930’s the Universe was a simple place All matter was made of atoms Atoms had a nucleus made from protons and neutrons surrounded by a cloud of electrons All the known matter in the Universe could be described by three particles

13. Finally - Cosmic Rays By 1926 it was clear that the Earth was bombarded by a high energy rain of protons from outer space – Cosmic Rays

14. Cosmic Ray research Scientists quickly started to study cosmic rays using the new cloud chamber detectors and photographic emulsions located on mountain tops or flown in balloons

15. The particle explosion New particles just kept coming………… Muon  (  ) 1936 Kaon (K-plus)  (   ) 1947 Kaon (K-zero)  (   ) 1947 Lambda  1951 Sigma (sigma-plus)    1953 Pion (pi-minus)  (   ) 1947 XI (xi-minus)    1952 Anti-Lambda  1958 Sigma (sigma-minus)    1953 Kaon (K-minus)  (   ) 1947 Pion (pi-plus)  (   ) 1947 Pion (pi-zero)  (   ) 1949 XI (xi-zero)    1959 Neutrino  (  ) 1955

16. Finding patterns Like Mendeleev, group particles with similar properties together Patterns Sub-structure In 1964 Murray Gell-Mann suggested that the many particles found could be made from just three quarks He called them up , down and strange But no free quarks seen……………….

17. Man-made cosmic rays By the 1960’s particle accelerators were operating in America (Berkeley - West coast, Brookhaven - Long Island NY and SLAC – Stanford California) and Europe (CERN – Geneva) Length 0.5m Energy of electron beam 20kV Length 3200m Energy of electron beam million times greater

18. Enter the quark In 1967 used SLAC to scatter electrons off protons Still the Rutherford scattering experiment, on a bigger scale! Results showed that proton had sub-structure Made up of three point like objects - quarks

19. The particles of matter Model of atom today Quarks and electrons are fundamental As far as we can tell no further sub-structure Proton – up up down (uud) Neutron – down down up (ddu) All ordinary matter in the Universe is made up from these three particles

20. So that’s that? Not quite! We can describe ordinary matter with three particles – two quarks (u and d) and the electron Remember to describe all the particles that were found using cosmic rays we needed a third quark – strange (s) There was also another particle the muon – just like the electron but heavier Where do these particles fit?

21. Back to the particle accelerators By the 1970’s large circular accelerators being built

22. Creating New Particles positron (e + ) electron (e - ) muon (  - ) antimuon (  + ) E=mc 2 !

23. Back to the particle accelerators One such accelerator was SPEAR a ring which collided electrons and positrons together In 1974 evidence for a fourth quark – charm (c) was seen at the SPEAR In 1975 evidence for a particle like the electron and the muon but much heavier – the tau (  )

24. Even more quarks! As accelerator energies increased still further yet another quark was discovered in 1977 – bottom (b) By now theorists were convinced that a pattern was beginning to emerge with families consisting of pairs of quarks and their matching electron like particles WHERE IS TOP (t)?

25. Will it ever end? Whilst the Americans built an accelerator to find the top quark At CERN LEP was built – a huge accelerator to collide beams of electrons and positrons

26. LEP

27. Inside the LEP tunnel LEP was 27000m in circumference Four bunches of electrons and positrons circulated inside the vacuum pipe One ten thousandth of a second for a complete circuit About one electron-positron collision per second Energy of electron beam ten million times greater than TV

28. ALEPH – a LEP particle detector

29. Will it ever end? In 1991 experiments at LEP proved that there are only three families of quarks and their associated electron like particles or leptons Found no evidence for quark sub-structure What about the sixth quark? Top quark discovered in 1995 at Fermilab in USA Number of different neutrinos = 2.994 ± 0.011 20 000 000 Rate

30. The matter particles First Generation Ordinary Matter Second Generation Cosmic Rays Third Generation Accelerators

31. The Standard Model

34. How do the fundamental particles get their mass? New concept needed: Higgs mechanism

35. The Higgs mechanism New field postulated that fills all space: the Higgs field All fundamental particles obtain their masses from interacting with the Higgs field The Higgs boson is the field quantum of the Higgs field (like the photon is the quantum of the e.m. field)

46. Results from LEP It should be around here! 95% Ruled Out

50. Supersymmetry: symmetry of fermions and bosons fermions bosons

54. The CERN LHC 4 Large Experiments The world’s most powerful particle accelerator - 2007

61. ALICE Size : 16 x 26 meters Weight : 10,000 tons

62. Alice Status First cosmics in TPC Sector

65. ATLAS Construction status: on track for collisions towards the end of 2007

67. Inner Detector Complete integrated Pixel end-cap with 6.6 M channels at CERN

70. CMS Assembly

71. CMS Solenoid

72. Transverse slice through CMS detector Click on a particle type to visualise that particle in CMS Press “escape” to exit

73. LHCb pit

75. So what has particle physics ever done for us?

76. The future The LHC at CERN is due to start operating in 2007.