Quark model for hadrons - CERN
Transcript of Quark model for hadrons - CERN
Qiang Zhao
Institute of High Energy Physics, CAS
and Theoretical Physics Center for Science Facilities (TPCSF), CAS
Quark model for hadrons
Institute of High Energy Physics, CAS
Hadron School, Rajamangala Univ. of Technology Isan,
Nakhon Ratchasima, Thailand, Feb. 29- April 4, 2016
Outline
Some facts about quarks; A brief review of hadron physics, introduction to non-relativistic constituent quark model (NRCQM) for baryons, and the question of “missing resonances”
Electromagnetic (EM) and strong interactions of baryons in NRCQM, quark model selection rules and symmetry breakings
Probing baryon resonances in meson photo- and electroproduction, and meson-nucleon scatterings
References:
N. Isgur and G. Karl, Phys.Rev. D18 (1978) 4187
N. Isgur and G. Karl, Phys.Rev. D20 (1979) 1191-1194
S. Godfrey and N. Isgur, Phys.Rev. D32 (1985) 189-231
S. Capstick and N. Isgur, Phys.Rev. D34 (1986) 2809
E. Eichten, K. Gottfried, T. Kinoshita, K.D. Lane, and T.-M. Yan, Phys.Rev. D17 (1978) 3090, Phys.Rev. D21 (1980) 313 E. Eichten, K. Gottfried, T. Kinoshita, K.D. Lane, and T.-M. Yan, Phys.Rev. D21 (1980) 203
F. E. Close, An introduction to quarks and partons, Academic Press, 1979
S. Capstick and W. Roberts, Prog.Part.Nucl.Phys. 45 (2000) S241-S331
Time line of sub-atomic physics
1897: electron
1919: proton
1932: neutron
1933: positron
1935: pion predicted by Yukawa Yukawa
C.-Y. Chao Anderson
Joliet-Curie Chadwick
Rutherford
Thomson
proton
neutron neutron
proton
pion
Elementary particle “Zoo” in
1963
“stable” hadrons meson resonances baryon resonances
Two “classes” of hadrons
“non-strange:” n, p, p, r, … “strange:” L, S, K, K*, …
X
S
L
N
K
p
m
e
K*
r
w
K2*
Y*
D
X*
From S. Olsen’s summer lecture in Beijing, 2010
1961: Gell-Mann, Nishijima & Nee’man: The Eightfold Way
Quarks as building blocks of hadrons: meson (qq), baryon (qqq)
Simple rules for quarks (Particle Data Group): 1) Quark has spin 1/2 and baryon number 1/3; 2) Quark has positive parity and antiquark has negative parity; 3) The flavor of a quark has the same sign as its charge.
S
n (dud) p (uud)
S–
(sdd)
X– (ssd)
S0, L (sud)
S+
(suu)
X0 (ssu)
I3
SU(3) octet
with JP=1/2+
0
1
2
–1 1
Gell-Mann - Nishijima:
Q=I3+Y/2=I3+(B+S)/2
333
=(3 6) 3
=(18) (810)
SU(3) multiplets of baryons made of u, d, and s
SU(3) decuplet 10
with JP=3/2+
S
D0(udd) D+(uud)
S*–
(sdd)
X*– (ssd)
S*0 (sud)
S*+
(suu)
X*0 (ssu)
I3 0
1
2
1
D–(ddd)
–(sss) 3
1
D++(uuu)
3/2 3/2
SU(3) multiplets of baryons made of u, d, and s
Decuplet 10:
–(sss)
m1
m2
m3
r1 r2
r3
2r
6/2
Jacobi coordinate
Symmetric spin wavefunction: S=3/2 Symmetric flavor wavefunction: sss Symmetric spatial wavefunction: L=0
A problem encountered: Violation of the Pauli principle and Fermi-Dirac statistics for the identical strange quark system?
• An additional degrees of freedom, Colour, is introduced.
• Quark carries colour, while hadrons are colour neutral objects.
3 3 3
= (3 6) 3
= (1 8) (8 10)
* e
e
Electron-Positron annihilations
Probe coloured quarks in electron-positron collisions
q
q
Hadrons m
m
* e
e
eq e
R êq2
(2/3)2 (1/3)2 (1/3)2 … u d s …
R êq2
q : u(3/2) d(-1/3) s(-1/3) c(2/3) b(-1/3) t(2/3) R
(2/3)2 (1/3)2 (1/3)2 [2/3]
[2/3] (2/3)2 [10/9]
[10/9] (1/3)2 [11/9]
[11/9] (2/3)2 [15/9]
But if quark carries color, one should have
R 3 êq2
R 3 êq2
q : u(3/2) d(-1/3) s(-1/3) c(2/3) b(-1/3) t(2/3) R
(2/3)2 (1/3)2 (1/3)2 [2/3]
[2/3] (2/3)2 [10/9]
[10/9] (1/3)2 [11/9]
[11/9] (2/3)2 [15/9]
2
10/3
11/3
5
10
y
J.J. Aubert et al., PRL 33, 1404 (1974) J.E. Augustine et al., PRL 33, 1406 (1974)
J
Also seen in pNe+e-X
R=2.2
>>2/3
1976 Nobel Prize:
B. Richter and S. C.-C. Ting
"for their pioneering work in the
discovery of a heavy
elementary particle of a new
kind"
Convention (Particle Data Group):
1) Quark has spin 1/2 and baryon number 1/3;
2) Quark has positive parity and antiquark has negative parity;
3) The flavor of a quark has the same sign as its charge.
Quarks are real building blocks of hadrons: meson (qq), baryon (qqq)
• Quarks are not free due to QCD colour force (colour confinement).
• Chiral symmetry spontaneous breaking gives masses to quarks.
• Hadrons, with rich internal structures, are the smallest objects in
Nature that cannot be separated to be further finer free particles.
Quantum Chromo-Dynamics: a highly successful theory for Strong Interactions
Conventional hadrons
Asymp. freedom
Co
nfi
ne
me
nt
Meson
Baryon
Remaining questions:
•What are the proper effective degrees of freedom for hadron internal structures?
•What are the possible color-singlet hadrons apart from the simplest conventional mesons (qq) and baryons (qqq)?
•What’s happening in between “perturbative” and “non-perturbative”?
•… …
Multi-faces of QCD: Exotic hadrons beyond conventional QM
Hybrid Glueball Tetraquark
Pentaquark Hadronic molecule
The study of hadron structures and hadron spectroscopy should deepen our insights into the Nature of strong QCD.
I. A brief review of hadron physics
and introduction to non-relativistic
constituent quark model (NRCQM)
• Atoms – 10–10 m
• Nuclei – 10–14 m
• Nucleons – 10–15 m
• Quark degrees of freedom:
(0.1~0.5)×10–15 m
Electromagnetic Probe(电磁探针)
Photon energy
E= 2p×197.3 MeV·fm/
Nucleon resonances
Photon
Basic assumptions of NRCQM
i) Chiral symmetry spantaneous breaking leads to the presence of
massive constituent quarks as effective degrees of freedom inside
hadrons.
ii) Hadrons can be viewed as quark systems in which the gluon fields
generate effective potentials that depend on the spins and positions
of the massive quarks.
Thus, meson is a qq system and baryon is made of qqq.
qq meson qqq baryon
Convention (Particle Data Group):
1) Quark has spin 1/2 and baryon number 1/3;
2) Quark has positive parity and antiquark has negative parity;
3) The flavor of a quark has the same sign as its charge.
Quarks as building blocks of hadrons: meson (qq), baryon (qqq)
• Quarks are not free due to QCD colour force (colour confinement).
• Hadrons, with rich internal structures, are the smallest objects in
Nature that cannot be separated to be further finer free particles.
Baryons in SU(6)O(3) symmetric quark model
Spin
Flavor
Spin-flavor
Spatial
We concentrate on the baryons made of u, d, s quarks.
Color
Baryon wavefunction as representation of 3-dimension permutation group:
s, r, , a
symmetric
For a three-quark Fermion system, the Pauli principle requires that the
total wavefunction is antisymmetric under exchange of any two quarks.
Therefore, the total wavefunction must be antisymmetrized.
Property of dimension-3 permutation group
e.g. The SU(2) spin
wavefunction for a three-
quark system
S
n (dud) p (uud)
S–
(sdd)
X– (ssd)
S0, L (sud)
S+
(suu)
X0 (ssu)
I3
SU(3) octet
with JP=1/2+
0
1
2
–1 1
Gell-Mann - Nishijima:
Q=I3+Y/2=I3+(B+S)/2
333
=(3* 6) 3
=(18) (810)
SU(3) multiplets of baryons made of u, d, and s
SU(3) decuplet 10
with JP=3/2+
S
D0(udd) D+(uud)
S*–
(sdd)
X*– (ssd)
S*0 (sud)
S*+
(suu)
X*0 (ssu)
I3 0
1
2
1
D–(ddd)
–(sss) 3
1
D++(uuu)
3/2 3/2
SU(3) multiplets of baryons made of u, d, and s
Decuplet 10:
–(sss)
Anti-decuplet 10:
+(sss)
333
Spatial wavefunction in a spin-independent potential
m1
m2
m3
r1 r2
r3
2r
6/2
Jacobi coordinate
Hamiltonian
Isgur, and Karl, PLB109, 72(1977); PRD18, 4187(1978); PRD19, 2653(1979)
With an equal mass for u, d, and s quark, and k=mqwh2/3, the Hamiltonian
can be expressed as
Jacobi coordinate
Harmonic oscillator wavefunction
m1
m3
r1 r2
r3
2r
6/2
Spatial wavefunction in a spin-independent potential
Total wavefunction of SU(6)O(3) symmetry
Isgur, and Karl, PLB109, 72(1977); PRD18, 4187(1978); PRD19, 2653(1979)
Anharmonic and spin-dependent potential
Based on the SU(6)O(3) symmetry, the quark model succeeded in the
classification of the baryon spectrum. But quantitative results could not
be expected since more elaborate details about the dynamics were
needed.
For instance, the Roper resonance P11(1440) was assigned to the radial
excitation state with N = 2, and L = 0, which was found to have lower
mass than the first orbital excition multiplets S11(1535) etc with N = 1
and L = 1. The inclusion of the anharmonic and spin-dependent quark
potential turned to be necessary.
N1/2
N=2, L=0
N1/2
N=1, L=1
P11(1440)
S11(1535)
n is the radial quantum number,
and L is the orbital angular
momentum.
Electromagnetic moments of ground state baryons
One of the most impressive successes of the NRCQM could be its
description of the electromagnetic moments of ground state baryons.
The simple assumption is that all constituent quarks are in S-wave
orbitals, i.e. except for the spin of the constituents, no orbital angular
momentum would contribute to the electromagnetic moment.
One essential point is that one cannot neglect the “color” degrees
of freedom at all. If one anti-symmetrizes the total wavefunction
without the color part taken into account, the ratio of the magnetic
moment between proton and neutron will be -1/2, which is far away
from reality.
The CQM is indeed tackling something essential, we are however
confronted with big difficulties to disentangle it based on this model
itself. More elaborate models are needed for the study the baryon
properties at more accurate level.
Lattice QCD studies, which are base on the first principle, are also
needed for understanding not only the non-perturbative phenomena,
but also successes of phenomenological models.
Baryon spectroscopy and “Missing resonances”
Are the constituent quarks good degrees of freedom for the
description of baryon spectroscopy?
Could it be possible to classify all baryon states observed in
experiment in the framework of QM? How many have been seen,
and how many are still missing?
What are the deviations? What causes the deviations? Where
the constituent quark model scenario must break down?
Does the Nature allow the existence of exotic hadrons, e.g.
pentaquarks?
Where to look for the anti-symmetric 20-plets?
How the constituent picture in the non-perturbative region is
connected to the partonic one in the perturbative region?
……
• The non-relativistic constituent quark model (NRCQM) makes
great success in the description of hadron spectroscopy:
meson (qq), baryon (qqq).
• However, it also predicted a much richer baryon spectrum, where
some of those have not been seen in pN scatterings.
– “Missing Resonances”.
p, 0
N, ½+
N*, L2I,2J
P33(1232) D
P11(1440)
S11(1535)
D13(1520)
…
“Missing baryon resonances in pN scattering
Dilemma:
a) The NRCQM is WRONG: quark-diquark configuration? …
b) The NRCQM is CORRECT, but those missing states have only weak
couplings to pN, i.e. small gpN*N. (Isgur, 1980)
Looking for “missing resonances” in N* N, KS, KL, rN, wN, N,
N …
(Exotics …)
N* u u d
d
d
u
u d
r
n
• Baryons excitations via strong and EM probes
p, 0
N, ½+
N*, D*, L2I,2J
P33(1232) D
P11(1440)
S11(1535)
D13(1520)
…
, 1
N, ½+
N*, D*
+ p D
D13
F15
Brief summary
The quark model achieved significant successes in the
interpretation of a lot of static properties of nucleons and the
excited resonances.
However, it also raised the famous puzzle of “missing
resonances”, which were predicted by the quark model in the
baryon spectroscopy, but have not been found in the p-N
scattering experiments.
By studying the baryon spectroscopy, baryon EM form factors,
and baryon couplings to mesons in meson photo- and
electroproduction, and meson-nucleon scatterings, we could
extract important information about the structure of baryons
and non-perturbative QCD dynamics.
For the heavy flavor system, the Cornell model was one of the
pioneering approaches and many consequent implications will
be covered by lectures on the NRQCD (Eichten) and NREFT
(Guo and Wang).