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Phy107 Fall 2006 1 From Last Time… Particles are quanta of a quantum field –Often called excitations of the associated field –Particles can appear and.

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Presentation on theme: "Phy107 Fall 2006 1 From Last Time… Particles are quanta of a quantum field –Often called excitations of the associated field –Particles can appear and."— Presentation transcript:

1 Phy107 Fall 2006 1 From Last Time… Particles are quanta of a quantum field –Often called excitations of the associated field –Particles can appear and disappear Particles interact by exchanging other particles –Electrons interact by exchanging photons This is the Coulomb interaction Electrons are excitations of the electron field Photons are excitations of the photon field Today More particles! Essay due Friday

2 Phy107 Fall 2006 2 Something unexpected Raise the momentum and the electrons and see what we can make. Might expect that we make a quark and an antiquark. The particles that make of the proton. –Guess that they are 1/3 the mass of the proton 333MeV e- -- e+  + Instead we get a muon, acts like a heavy version of the electron , Muon mass: 100MeV/c 2, electron mass 0.5 MeV/c 2

3 Phy107 Fall 2006 3 Accelerators What else can we make with more energy? Electrostatic accelerator: Potential difference V accelerate electrons to 1 MeV Linear Accelerator: Cavities that make EM waves particle surf the waves - SLAC 50 GeV electrons Cyclic Accelerator: Circular design allows particles to be accelerated by cavities again and again –LEP 115 GeV electrons –Tevatron 1 TeV protons –LHC 7 TeV protons(starts next year)

4 Phy107 Fall 2006 4 CERN (Switzerland) 27 km CERN, Geneva Switzerland LHC Cyclic accelerator 27km, 14TeV 7+7=14

5 Phy107 Fall 2006 5 Detectors are required to determine the results of the collisions. CDF: Collider Detector Facility at Fermilab Measuring particle collisions

6 Phy107 Fall 2006 6 Fundamental Particles In the Standard Model the basic building blocks are said to be ‘fundamental’ or not more up of constituent parts. Which particle isn’t ‘fundamental’: A. electron B. muon C. photon D. proton

7 Phy107 Fall 2006 7 What have we learned? Matter is made of atoms Leptons e e Quarks d u “ Atoms are made of leptons and quarks “ Atoms are made of leptons and quarks Interact via different forces carried by particles, photons…

8 Phy107 Fall 2006 8 Neutrino Neutrino was first detected in 1956 The neutrino has –Zero charge, spin 1/2, almost zero mass Electron has –Charge -e, spin 1/2, mass 0.5 Mev/c 2 Electron and neutrino generically called leptons Seen before in the weak interaction. Fred Reines, Clyde Cowan, at the Hanford nuclear reactor

9 Phy107 Fall 2006 9 Protons/Neutrons are composite

10 Phy107 Fall 2006 10 Protons, neutrons, and quarks Protons and neutrons are made up of –‘up’ quarks and ‘down’ quarks Charge +(2/3)e -(1/3)e Spin 1/2 Mass (MeV/c 2 ) 3 6 Up Down

11 Phy107 Fall 2006 11 Question A neutron is a composite particle consisting of three quarks (up=charge +2/3e, and down = charge -1/3e). Which is the structure of the neutron. A.up, up, up B.up, up, down C.up, down, down Total charge: +2e +e 0 Neutron has zero total charge

12 Phy107 Fall 2006 12 Protons & Neutrons To make a proton: We bind 2 up quarks of Q = +2/3 and 1 down quark of Q = -1/3. The total charge is 2/3 + 2/3 + (-1/3) = +1 ! To make a neutron: We bind 2 down quarks of Q= -1/3 with 1 up quark of Q = +2/3 to get: (-1/3) + (-1/3) + (2/3) = 0 !

13 Phy107 Fall 2006 13 Hierarchy of structure R ~ 10 -15 m (strong) protons and neutrons are made from quarks R ~ 10 -10 m (electromagnetic) Atoms are made from protons, neutrons, and electrons R > 10 6 m (gravitational) We’ll talk about the rest of the universe later Leptons e e Quarks d u

14 Phy107 Fall 2006 14 What about the muon? The muon found early on. –Heavy version of the electron. Otherwise would have been fairly simple! e- -- e+  + , Muon mass: 100MeV/c 2, electron mass 0.5 MeV/c 2

15 Phy107 Fall 2006 15 More particles In 1975, the tau lepton was discovered at SLAC.(Nobel prize, 1995) Just like the electron and muon, but 3500 times heavier than the electron –Same charge, same spin, but different mass. Made this particle by creating more energy. Both the muon and tau have Muon-neutrino Tau-neutrino (detected in 2000) Stanford linear accelerator center (SLAC)

16 Phy107 Fall 2006 16 The particle garden Particle physics at this point has settled on a countable number of ‘fundamental particles’. The bad news - there are: –(6 leptons +6 quarks)+ (4 electroweak bosons +8 gluons +1 graviton) =25 fundamental particles, not counting antiparticles! The good news: –These are not just random, but have some relationships that let us understand the ideas without thinking immediately about all the particles.

17 Phy107 Fall 2006 17 Three electron-like particles Charge -e Spin 1/2 Mass (MeV/c 2 ) 0.5 106 1,777 Electron Muon Tau These are referred to as three ‘generations’ of particles. Difference between them is only mass

18 Phy107 Fall 2006 18 Three neutrinos Charge 0 0 0 Spin 1/2 Mass (MeV/c 2 ) ~0 Electron-neutrino Muon-neutrino Tau-neutrino These are referred to as three ‘generations’ of particles. Difference between them is only mass

19 Phy107 Fall 2006 19 Six quarks Charge +(2/3)e -(1/3)e Spin 1/2 Mass (MeV/c 2 ) 3 6 Up Down +(2/3)e -(1/3)e 1/2 1,300 100 Top Bottom +(2/3)e -(1/3)e 1/2 175,000 4,300 Charmed Strange

20 Phy107 Fall 2006 20 Quarks: Heavy, Heavier, Heaviest  6 different kinds of quarks.  Matter is composed mainly of up quarks and down quarks bound in the nuclei of atoms.  Masses vary dramatically (from ~0.005 to 175 [GeV/c 2 ])  Heavier quarks are unstable, rapidly decay to lighter quarks Mass [GeV/c 2 ] Gold atom Silver atom Proton Example: t  b (~10 -23 [s]) b  c (~10 -12 [s]) c  s (~10 -12 [s]) s  u (~10 -7- 10 -10 [s]) More on quark decays later…

21 Phy107 Fall 2006 21 Three ‘generations’ of particles Three generations differentiated primarily by mass (energy). First generation –One pair of leptons, one pair of quarks Leptons: –Electron, electron- neutrino. Quarks: Up, down. All have spin 1/2

22 Phy107 Fall 2006 22 The generations of ‘matter particles’ Light Heavier Heaviest

23 Phy107 Fall 2006 23 Antiparticles Each of these has an antiparticle, different only by charge. Electron antiparticle = positron Muon antiparticle = anti-muon Tau antiparticle = anti-tau Matter and anti-matter can annihilate creating energy

24 Phy107 Fall 2006 24 Making more composite particles The forces which hold the protons and neutrons together in the nucleus are VERY strong. They interact via the STRONG FORCE. Protons and neutrons are among a class of particles called “hadrons” (Greek for strong). Particles made of quarks. Baryons are hadrons which contain 3 quarks (no anti-quarks). Anti-baryons are hadrons which contain 3 anti-quarks (no quarks ).

25 Phy107 Fall 2006 25 Most of the mass is in the binding energy. Use up and down quarks uds Charge Q Mass +2/3-1/3 ~5 [MeV/c 2 ]~10 [MeV/c 2 ]~200 [MeV/c 2 ] Quarkupdownstrange uuddss u u d Proton Q = +1 M=938 MeV/c 2 d u d Neutron Q = 0 M=940 MeV/c 2

26 Phy107 Fall 2006 26 Are there baryons other than protons and neutrons? Other quarks can combine to form other baryons. For example : u s d This combination is called a Lambda baryon, or  0 for short Charge 0: (2/3) + (-1/3) + (-1/3) = 0

27 Phy107 Fall 2006 27 More Baryons s u d Lambda (  ) Q = 0 M=1116 MeV/c 2 s u u Sigma (   ) Q = +1 M=1189 MeV/c 2 s u d Sigma (   ) Q = 0 M=1192 MeV/c 2 s d d Sigma (   ) Q = -1 M=1197 MeV/c 2 uds Q Mass +2/3-1/3 Quarkupdownstrange uuddss ~5 [MeV/c 2 ]~10 [MeV/c 2 ]~200 [MeV/c 2 ] Excited state - Higher energy/mass

28 Phy107 Fall 2006 28 Another baryon: u Delta baryon, or  ++ for short. Charge: +2 (2/3) + (2/3) + (2/3) = +2 ! u u What’s this baryon’s electric charge? A. 0 B. +1 C. +2

29 Phy107 Fall 2006 29 Mesons They are formed when a quark and an anti-quark “bind” together. So far we’ve only seen 3 quark combinations. There are also 2 quark combinations. The hadrons: 2 quarks, meson and 3 quarks, baryon. u d What’s the charge of this particle? c d Q=+1, and it’s called a  + Q= -1, and this charm meson is called a D - s d What’s the charge of this particle? Q= 0, this strange meson is called a K 0

30 Phy107 Fall 2006 30 Leptons and quarks: what’s the difference? One important difference is how they interact. We said the Coulomb interaction is between particles with electrical charge. Understood by exchanging photons. The other interactions: –Weak –Strong –Gravitational Particles understood/defined by how they interact

31 Phy107 Fall 2006 31 Electromagnetic Force In the Standard Model particles are often classified by what forces they interact via. Which of these particle does not interact with the electromagnetic force: A. electron B. muon C. photon D. quark

32 Phy107 Fall 2006 32 Interactions between particles The modern view of forces is in terms of particle exchange. These are ‘virtual’ particles of the fields created by the particle charges. This shows Coulomb repulsion between two electrons. It is described as the exchange of a photon.

33 Phy107 Fall 2006 33 Four Gauge forces

34 Phy107 Fall 2006 34 Exchange bosons Each interaction has one or more associated particles that mediate the interaction. The exchange particles are associated with the known interactions Electro- photon(1) magnetic Weak W +, W - and Z o (3) Strong gluons (8) Gravity graviton(1) InteractionMediating particle(s)Number These all have integer spins, hence are bosons

35 Phy107 Fall 2006 35 Bosons

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