Experimental results on nucleon structure Lecture I. National Nuclear Physics Summer School 2013
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1 Experimental results on nucleon structure Lecture I Barbara Badelek University of Warsaw National Nuclear Physics Summer School 2013 Stony Brook University, July 15 26, 2013 Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
2 Outline Course literature 1 Course literature 2 Introduction Kinematics, experiments and observables Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
3 Course literature Course literature 1 D. H. Perkins, Introduction to high energy physics, CUP 2000 (4th edition or later). 2 B.R. Martin and G. Shaw, Particle Physics Wiley 1997 or later. 3 A. W. Thomas and W. Weise, The structure of the nucleon, Wiley-VCH B. Povh, et al., Particles and Nuclei, Springer 2008 (6th edition or later) 5 R. G. Roberts, The structure of the proton: Deep inelastic scattering, CUP and original papers, e.g. for spin see C. A. Aidala et al., arxiv: v2 (1 April 2013) Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
4 Outline Introduction 1 Course literature 2 Introduction Kinematics, experiments and observables Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
5 Outline Introduction 1 Course literature 2 Introduction Kinematics, experiments and observables Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
6 Two limits of research Introduction Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
7 Reminder: scales (distance, energy, mass,...) and constants r 1 fm (presently: an object is pointlike if its dimensions < fm = m) E 1 GeV m 1 GeV/c 2 Important constants: Planck constant, h J s (quantum physics must be applied), speed of light, c m/s (relativistic physics must be applied), fine structure constant, α = e2 4πɛ 0 c Heaviside Lorentz system: 1 = = c = ɛ 0 = µ 0 will be used Very useful quantity: c = GeV fm = α = e2 4π Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
8 Elementary building blocks of matter Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
9 Introduction Photo: BB, 2012 Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
10 Do we REALLY understand the structure of matter? Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
11 Reminder: dimensions of atom and its constituents Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
12 Baryons: nucleons & Co. Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
13 Mesons Introduction Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
14 Types and properties of interactions (forces) mass (GeV) range (m) coupling constant /137 1 time (s) Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
15 Unification of interactions at energy of GeV??? > ENERGY Add supersymmetry: fermions bosons Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
16 Standard Model of elementary interactions Family of elementary objects: at least 36 members of which at least 12 are interaction (or force) carriers. In our conditions we see at least 4 interactions; their relative strength changes with energy: strong electromagnetic May be that immediately after the Big Bang all interactions had similar strength Grand Unification Theories (GUT), at E > GeV (proton mass: 1 GeV; largest proton energy in an accelerator (LHC) now: 4 TeV, soon: 7 TeV). Standard Model: perfectly agrees with experiment but DOES NOT predict several parameters, e.g. particle masses and features of forces (about 20 free parameters). Also: gravitation??? Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
17 Interactions; probability amplitude; cross section (Electromagnetic) interaction = emission and absorption of a virtual photon, γ. Momentum transfer: k = ( p p ) Energy transfer: ν = (E E ). p, E p', E' Define (negative) 4-momentum transfer squared (photon virtuality): Q 2 = q 2 = ( p p ) 2 (E E ) 2 = M 2 γ 0! Define cross-section, σ: σ probability = f 2 Observe that f t (time of the emission process) 1 so that f = 1 Mγ 2 Q or: f = e Q = whole interaction: f e1e2 Q 2 dσ and dq e2 1e Q 4 This probability amplitude is universal, i.e. describes several processes. Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
18 Feynman diagrams in Coulomb interactions Scattering amplitude: f ee dσ = Q2 dq e4 2 Q α2 4 Q 4 For 2γ exchange σ α 4, ( ) 2 i.e. σ is α 2 1 smaller than for 1γ exchange. 137 Scattering from an effective charge ef : dσ dq α2 F 2 (Q 2 ) 2 Q 4 F 1 with limiting conditions: lim F (Q 2 ) = 0 and lim F (Q 2 ) = 1 Q 2 Q 2 0 Q 2 where F (Q 2 ) elastic nucleon (target) form factor. Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
19 Electrons in nucleon structure experiments Electron nucleon (nucleus) scattering; electrons point-like, r < m Background of ee scattering easy to separate (except from forward scattering). (Electromagnetic) processes which yield information on proton structure: Rutherford scattering, e p e p M 2 γ < 0, Q2 > 0 Annihilation: e + e p p, M 2 γ > 0, Q2 < 0 Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
20 Strong interactions (between quarks) Generally an interaction between 2 particles is an exchange of a boson of mass m. g Broken line = a boson g, g 0 = charges Scattering amplitude: f(q 2 gg 0 ) = Q 2 + m 2 g 0 BUT α s 1!!!! multigluon exchanges!!! Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
21 Strong coupling constant Q 2 < 1 GeV 2 Confinement Q 2 Asymptotic freedom!! Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
22 Residual strong interaction (in a nucleus) Final state quarks dress up into hadrons = fragmentation. Factorization theorem: physics particles cross section = (calculable QCD parton cross-section) (universal long-distance functions) Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
23 Weak interactions Introduction Scattering amplitude: f(q 2 ) = g 2 Q 2 + m 2 Z(W ) Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
24 Outline Introduction Kinematics, experiments and observables 1 Course literature 2 Introduction Kinematics, experiments and observables Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
25 Why high energies? Introduction Kinematics, experiments and observables Searching for elementary components demands using high energy beams since: some elementary particles are heavy (e.g. m Z 0 90m p ), and energy, E = mc 2, is needed to produce them; goal is to investigate small distances, x 1 fm, and since x p then p large and = p large too. Another argument: λ small = p large since λ h/p. Example 1: electrons of λ 1 fm have E 0.2 GeV. Example 2: investigating protons, < 1 fm, demands Q 2 > 1 GeV 2. Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
26 Kinematics, experiments and observables Reminder: centre-of-mass vs laboratory systems A beam particle A hits a target particle B: p 2 = ( p A + p B ) 2 (E A + E B ) 2 = m 2 A m2 B + 2( p A p B E A E B ) = (E cms ) 2 Consider a fixed target experiment, i.e. p B = 0 (E B = m B ); here p 2 = (E cms ) 2 = m 2 A m2 B 2 E A m B or, if particles masses are negligible with respect to their energies (momenta): E A = (Ecms ) 2 2m B Consider a collider experiment, i.e. p A p B (or: ( p A, p B ) = π): p 2 = (E cms ) 2 = m 2 A m2 B + 2( p A p B E A E B ) or, if particle masses are negligible with respect to their energies (momenta): p 2 = (E cms ) 2 4E A E B Important example: LHC operating at 7 TeV per proton beam: E cms = 2 7 TeV = 14 TeV If such E cms were to achieve in a fixed-target experiment then a beam of E A TeV had to be prepared!!!! Not possible... (Compare: highest observed energy of cosmic rays: 10 9 TeV) Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
27 Types of high energy experiments Kinematics, experiments and observables e.g. COMPASS/CERN e.g. LHC/CERN e.g. ILC (planned) Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
28 Kinematics, experiments and observables How many variables needed to describe a reaction? Consider elastic (ep ep) and inelastic (ep ex) interactions where the initial state (i.e. masses and energies) is known. ep ep ep ex initial state known known final state 2 particles x 4 variables 8 variables 8 variables -4 eqs (en.-mom. conservation) (azimuthal angle, ϕ) 3 3 known masses in the final state 1 variable 2 variables Thus for elastic scattering: 1 variable is enough, e.g. Q 2 ; here also: W = M (W - effective mass of the X system, M - proton mass). Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
29 Kinematics, experiments and observables Inelastic electron proton scattering For the inelastic scattering 2 variables needed, e.g. Q 2 and ν. Try to find a relation W Q 2, ν. In the bottom vertex: Energy conservation: ν + M = E X Momentum conservation: Q 2 = k 2 ν 2 = p 2 X ν 2 Result: W 2 = 2Mν + M 2 Q 2 (1) Q 2 = ( p p ) 2 (E E ) 2 = 2m 2 2pp cos ϑ + 2EE 4EE sin 2 ϑ 2 (2) Q 2 W = M W 1 W 2 x Define: x = Q2 2Mν so that for elastic: x = 1 or W = M and for inelastic: x < 1 or W > M 2Mν (3) Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
30 Kinematics, experiments and observables Nucleon structure main research centres In red running experiments, in green future ones. SLAC (closed): several experiments, E e < 50 GeV, also polarised. CERN: µ, E µ: GeV, naturally polarised; proton and deuteron targets. BCDMS (completed) EMC (completed) NMC (completed) SMC (spin, completed) COMPASS (spin) FNAL: exp. E665, µ, E µ = 470 GeV. HERA (closed): e p collider, 28 GeV GeV H1 (being analysed) ZEUS (being analysed) HERMES, electrons, E e = 27 GeV on fixed-target (spin, being analysed) RHIC: p-p, 250 GeV GeV, polarised STAR (also spin) PHENIX (also spin) JLAB: several experiments, E e < 6 GeV (also spin); soon E e < 12 GeV. LHC (CMS, ATLAS): p-p, 4 TeV + 4 TeV; soon: 7 TeV + 7 TeV. Large Hadron-electron Collider, LHeC and/or Electron Ion Collider, EIC: e p and e A Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
31 Examples of detectors QWEAK/JLAB Introduction Kinematics, experiments and observables HERMES/DESY H1/DESY H1 kinematics Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
32 Kinematics, experiments and observables Acceptance of nucleon structure experiments Electron beams: high statistics, high systematics (radiative processes), cheap Muon beams: low statistics, low systematics, expensive Proton beams: complicated analysis. Barbara Badelek (Univ. of Warsaw ) Experimental results on nucleon structure, I NNPSS / 32
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