Elementary Particle Physics Research

Achim Geiser, DESY Hamburg Summer Student Lecture, 30.7.10

Scope of this lecture:

„ Introduction to particle physics for non-specialists ‰rather elementary ‰more details -> specialized lectures ‰particle physics in general thanks to B. Foster for some of the nicest slides/animations other sources: ‰slight emphasis on DESY-related topics www pages of DESY and CERN

30.7.10 A. Geiser, Particle Physics 1 What is Particle Physics?

30.7.10 A. Geiser, Particle Physics 2 What is a „particle“?

„ Classical view: particles = discrete objects. energy concentrated into finite space with definite boundaries. Particles exist at a specific location. -> Newtonian mechanics Isaac Newton „ Modern view: particles = objects with discrete Niels quantum numbers, e.g. charge, mass, ... Bohr not necessarily located at a specific position. (Nobel 1922) (Heisenberg uncertainty principle) can also be represented by wave functions (Quantum mechanics, particle/wave duality)

Louis Werner Erwin de Broglie Heisenberg Schrödinger (Nobel 1933) (Nobel 1929) (Nobel 1932) 30.7.10 A. Geiser, Particle Physics 3 What is „elementary“?

Greek: atomos = smallest indivisible part

Dmitry Ivanowitsch Mendeleyev 1868 (elements)

Ernest Rutherford 1911 (nucleus)

(Nobel 1908) Murray Gell-Mann 1962 (quarks)

(Nobel 1969)

30.7.10 A. Geiser, Particle Physics 4 History of basic building blocks of matter 0 − − + οο Σ + π − Κ−ΔΛ+Δ motivation: πΔπΔ0 pΩ + find Κ+ Κ smallest + Super- possible number symmetry

AD

30.7.10 A. Geiser, Particle Physics 5 Which Interactions? Three

30.7.10 A. Geiser, Particle Physics 6 The Forces in Nature

at ~ 1 GeV

30.7.10 A. Geiser, Particle Physics 7 What we know today

GGrraavviittyy g s s - upu charmc topt gluon -

er

er

i i tthhee

r γ r Quarks Quarks downd s bottomb strange photon ar ar gghhoosstt aatt

C

C νe νμ ντ W tthhee e-neutrino μ-neutrino τ-neutrino

W boson ce ce

r r ffeeaasstt

o e μ τ Z o Leptons

F Leptons electron muon tau Z boson F II IIII IIIIII HiggsHiggs GGeenneerraattiioonnss ooff BosonBoson?BosonBoson? mmaatttteerr 30.7.10 A. Geiser, Particle Physics 8 The Power of Conservation Laws

„e.g. radioactive neutron decay: - not visible n p + e + νe

„Pauli 1930:

Wolfgang Pauli

(Nobel 1945)

30.7.10 A. Geiser, Particle Physics 9 confirmation: neutrino detection

„e.g. reversed reaction: νe+ n p + e extremely rare! Frederick Reines (absorption length ~ 3 light years Pb) (Nobel 1995) „first detection: 1956 (!) Reines and Cowan, neutrinos from nuclear reactor

30.7.10 A. Geiser, Particle Physics 10 The power of symmetries: Parity

„ Will physical processes look the same when viewed through a mirror?

„ In everyday day life: violation of parity symmetry is common „natural“: our heart is on the left

„spontaneous“: cars drive on the right Eugene (on the continent) Wigner „ What about basic interactions? (Nobel 1963) „ Electromagnetic and strong interactions conserve parity!

30.7.10 A. Geiser, Particle Physics 11 The power of symmetries: Parity

Lee & Yang 1956: weak interactions violate Parity experimentally verified by Wu et al. 1957: Chen Ning Yang

(Nobel 1957) spin Tsung -Dao consequence: Lee neutrinos are always Chieng Shiung lefthanded ! Wu (antineutrinos righthanded) 30.7.10 A. Geiser, Particle Physics 12 The Power of Quantum Numbers

„ 1948: discovery of muon Who ordered THAT ? „ same quantum numbers as electron, except mass (Nobel 1988) I.I. Rabi (Nobel 1944) - - „muon decay: μ -> νμ e νe conservation of Leon M. Melvin Jack Ledermann Schwartz Steinberger „ electric charge -1 0 -1 0 „ lepton number: 1 1 1 -1 ν = ν (1955)

„ „muon number“: 1 1 0 0 νμ = νe (1962) „ „ There is a distinct neutrino for each charged lepton 30.7.10 A. Geiser, Particle Physics 13 The Power of Precision

„ Precision measurements of shape and height of Z0 resonance at LEP I (CERN 1990’s)

ν number of ν (light) neutrino ν

flavours = 3 Gerardus Martinus t’Hooft Veltman (Nobel 1999)

e+e- -> Z0

30.7.10 A. Geiser, Particle Physics 14 Can we “see” particles?

Luis Walter Alvarez (Nobel 1968) we can!

bubble chamber photo

Donald Arthur Glaser (Nobel 1960) 30.7.10 A. Geiser, Particle Physics 15 A generic modern particle detector

30.7.10 A. Geiser, Particle Physics 16 Particle Physics = People

30.7.10 A. Geiser, Particle Physics 17 Why do we need colliders?

„ early discoveries in cosmic rays, but

„ need controlled Mont Blanc conditions

V.F. Hess E (Nobel 1936) „m = c2 Albert Einstein CERN (Nobel 1921) need high energy to discover new heavy particles LEP/LHC „ colliders = microscopes (later) 30.7.10 A. Geiser, Particle Physics 18 Strong Interactions: Quarks and Colour

„ strong force in nuclear interactions = „exchange of massive pions“ between nucleons = residual Van der Waals-like interaction

Hideki Yukawa (Nobel 1949) n „ modern view: π (Quantum Chromo-Dynamics, QCD) exchange of massless gluons p between quark constituents

„similar“ to electromagnetism (Quantum Electro-Dynamics, QED) 30.7.10 A. Geiser, Particle Physics 19 The Quark Model (1964)

arrange quarks (known at that time) into flavour-triplett

=> SU(3)flavour symmetry Q=-1/3 Q=2/3

d u treat all known hadrons S=0 (protons, neutrons, pions, ...) as objects composed of two or three such quarks (antiquarks)

Murray S=-1 Gell-Mann s (Nobel 1969) 30.7.10 A. Geiser, Particle Physics 20 Colour

Quark model very successful, but seems to violate ++ quantum numbers (Fermi statistics), e.g. Δ =↑↑↑uuu => introduce new degree of freedom:

q g g q q gggg qq g g q

„ 3 coulours -> SU(3)colour qqq = qq = white!

30.7.10 A. Geiser, Particle Physics 21 Screening of Electric Charge

„ electric charge polarises vacuum -> virtual electron positron pairs

„ positrons partially screen electron charge

„ effective charge/force

(Nobel 1965) ‰ decreases at large distances/low energy (screening) ‰ increases at small distance/large energy

30.7.10Sin-Itoro Julian Richard P. A. Geiser, Particle Physics 22 Tomonaga Schwinger Feynman Anti-Screening of Coulour Charge! quark-antiquark pairs -> screening gluons carry colour -> gg pairs -> anti-screening!

(Nobel 2004)

asymptotic

confinement freedom

1/r2~E2,

30.7.10 A. Geiser, Particle Physics 23 Measurements of the Running coupling αs

(HERA) (LEP, PETRA)

30.7.10 A. Geiser, Particle Physics 24 calculation of proton mass in QCD from lattice gauge theory:

p

spontaneous breakdown of

“chiral symmetry” (left-right-symmetry) Yoichiro yields QCD “vacuum” expectation value Nambu => proton mass (Nobel 2008) => most of the visible mass of the universe! 30.7.10 A. Geiser, Particle Physics 25 How to detect Quarks and Gluons?

Jets!

hadrons Example of the hadron production in e+e- q e+ e- annihilation in the JADE q detector at the PETRA e+e- collider at DESY, hadrons Germany. Georges „ cms energy 30 GeV. Charpak 2-jet „ Trajectories of charged particles reconstructed in drift chambers event (gas ionisation detectors). (Nobel 1992) „ Photons - dotted lines - detected by lead-glass Cerenkov counters. „ Two opposite jets.

30.7.10 A. Geiser, Particle Physics 26 Discovery of the Gluon (1979)

q PETRA at DESY: look for

t

γ

g Björn Wiik Paul Söding

q 3-jet event TASSO event picture Günter Wolf Sau Lan Wu (EPS prize 1995) 30.7.10 A. Geiser, Particle Physics 27 How to resolve the structure of an object?

scattering image e.g. X-rays probe (Hasylab, FLASH, accelerator PETRA III, XFEL) E~ keV

-> structure of a biomolecule

30.7.10 A. Geiser, Particle Physics 28 Howto resolvethestructureof theproton? microscope: resolution ~ 10-18 m = 1/1000 of size of a proton low resolution -> small instrument high resolution -> large instrument

Data taking -> summer 2007. Data analysis -> 2014.

30.7.10 A. Geiser, Particle Physics 29 Inside the proton

Low Q2 (large λ) Jerome I. Henry W. Richard E. 2 Medium Q (medium λ) Friedmann Kendall Taylor (Nobel 1990)

Large Q2 (short λ)

At higher and higher resolutions, the quarks emit gluons, which also emit gluons, which emit quarks, which……. 2 -18 30.7.10At highest Q A. ,Geiser, λ ~ 1/QParticle ~ Physics 10 m 30 Example: Higgs cross section at LHC gluons in p from HERA -> predict Higgs at LHC

30.7.10 A. Geiser, Particle Physics 31 Weak Interactions

The Theory of GLASHOW, SALAM and WEINBERG ~ 1959-1968

(Nobel 1979)

Theory of the unified weak and electromagnetic interaction, transmitted by exchange of “intermediate vector bosons”

mass generated by Higgs field

30.7.10 A. Geiser, Particle Physics 32 Discovery of the W and Z (1983)

„ To produce the heavy W and Z bosons (m ~ 80-90 GeV) need high energy collider! „ 1978-80: conversion of SPS proton accelerator at CERN into proton-antiproton collider challenge: make antiproton beam!

„ success! Z0 -> e+e- UA1 -> first W and Z produced 1982/83 (Nobel 1984)

Simon Carlo van der Rubbia Meer

30.7.10 A. Geiser, Particle Physics 33 Electroweak Physics at HERA

Neutral Current (NC) interactions

e

Charged Current (CC) interactions

e

30.7.10 A. Geiser, Particle Physics 34 Weak interactions are "left-handed"

„ lefthanded electrons interact (CC) Polarized CC Cross Sections e-

„ righthanded electrons do not! e-

„ cross section linearly proportional σ to polarization

left polarization e± p e± p right polCC = (1± Pe)⋅σ unpolCC

30.7.10 A. Geiser, Particle Physics 35 Electroweak Unification

NC

CC

2 MW 30.7.10 A. Geiser, Particle Physics 36 The Quest for Unification of Forces

Electroweak Unification

Grand Unified Theories ?

Superstring Theories ?

Maxwell’s equations

strong Big Bang electric

magnetic

weak gravity

30.7.10 A. Geiser, Particle Physics 37 Antimatter relativistic Schrödinger equation P.A.M. (Dirac equation) Dirac two solutions: (Nobel 1933) one with positive, one with negative energy Dirac: interpret negative solution as 1932 antielectrons (positrons) found in conversion of energy into matter C.D.Anderson (Nobel 1936) 1995 antihydrogen consisting of antiprotons and positrons produced at CERN

In principle: antiworld can be built from antimatter In practice: produced only in accelerators and in cosmic rays 30.7.10 A. Geiser, Particle Physics 38 The Matter Antimatter Puzzle

Why does the Universe look like this not that?

As far as we can see in universe, no large-scale antimatter.

30.7.10-> need A. Geiser, CP Particle violation! Physics 39 CP symmetry

Parity (reflection)

Charge (black → C Conjugation white)

P

Like weak interaction, symmetric under CP (at first sight!) Can there be small deviations from this symmetry? 30.7.10 A. Geiser, Particle Physics 40 CP violation in B meson decays

Example: measurement from BaBar at SLAC (also Belle at KEK)

B and anti-B are indeed different

(also found earlier for K decays: )

Val L. Fitch data taking stopped.

James W. Cronin (Nobel 1980) Belle/Super-Belle continuing. M. Kobayashi T. Maskawa (Nobel 2008) 30.7.10 A. Geiser, Particle Physics 41 How much do Neutrinos weigh? from the lightest ... Standard Model has mν = 0

-> evidence for mν = 0 forces

see lecture C. Hagner

30.7.10 A. Geiser, Particle Physics 42 The Mystery of Mass

topt charmc upu d s down strange

. . νe e-neutrino b . νμ bottom e μ-neutrino electron . ντ μ τ-neutrino muon τ 30.7.10 A. Geiser, Particle Physics tau 43 Fermion Mass from Higgs field?

very brilliant scientist (fermion) works with speed of light! room = vacuum -> “massless” people = Higgs vacuum expectation value

30.7.10 A. Geiser, Particle Physics 44 Fermion Mass from Higgs field?

scientist becomes famous! enters room with people

30.7.10 A. Geiser, Particle Physics 45 Fermion Mass from Higgs field?

people cluster around him hamper his movement/working speed -> he becomes “massive”!

30.7.10 A. Geiser, Particle Physics 46 Higgs Search at the Tevatron

30.7.10 A. Geiser, Particle Physics 47 The Quest for the Higgs at LHC

Higgs production:

Higgs decay: depending on mass, Higgs might be found within first two years of LEP LHC physics operation!

30.7.10 A. Geiser, Particle Physics 48 CMS Z->μμ candidate

CTD

30.7.10 A. Geiser, Particle Physics 49 Supersymmetry

„A way to solve theoretical problems with Unification of Forces: Supersymmetry „ For each existing particle, introduce similar particle, with spin different by 1/2 unit

30.7.10 A. Geiser, Particle Physics 50 Supersymmetry

„double number of particles:

„ not seen at LEP, HERA, Tevatron ... -> must be heavy! „ hope to see them at LHC !

30.7.10 A. Geiser, Particle Physics 51 Unification and Superstrings

To include gravity in unification of forces, need Superstrings (Supersymmetric strings)

30.7.10 A. Geiser, Particle Physics 52 Superstring interaction

30.7.10 A. Geiser, Particle Physics 53 Extra Dimensions?

„ Superstrings require more than 3+1 dimensions „ additional “extra” dimensions -> “curled up” - could be as large as a mm!

potentially measurable effects, even at HERA! no evidence so far 30.7.10 A. Geiser, Particle Physics 54 Cosmology

increasing energy -> going further backwards in time in the universe -> getting closer to the Big Bang

30.7.10 A. Geiser, Particle Physics 55 ElectroweakElectroweakGrandGrand AtomsProtonsAtomsProtonseraeraGalaxyGalaxyunificationunification andand andand Hasylab, lightNucleineutronslightNucleineutronseraera eraera areare formform FLASH, formationformation3000001010-10-4 syearss PETRA III, formed300000-35 years formed100010 M yearss HERA/LEPXFEL QuarksQuarksThe Universe combinecombine totobecomes makemake protonsprotons andand100 neutronsneutrons s InflationGalaxiestransparentElectroweak ceases, begin and force to expansion fills form splits with LHC/ILC continues.lightProtons Grand and neutrons Unification breaks.combine Strong to andform helium electroweaknuclei forces become distinguishable You!

30.7.10 A. Geiser, Particle Physics 56 Elementary Particle Physics is exciting!

„ We already know a lot, but many open issues

I am bu stil t n l co ow nfu I a sed at m c , a m onf uch use hig d le her vel!

„ Exciting new insights expected for the coming decade!

30.7.10 A. Geiser, Particle Physics 57