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Eta and eta prime mesons

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Eta and eta prime mesons
Composition
η
 : ≈


η′
 : ≈
StatisticsBosonic
FamilyMesons
InteractionsStrong, Weak, Gravitation, Electromagnetic
Symbol
η
,
η′
AntiparticleSelf
Mass
η
 : 547.862±0.018 MeV/c2
[1]

η′
 : 957.78±0.06 MeV/c2
[1]
Mean lifetime
η
: (5.0±0.3)×10−19 s
,
η′
: (3.2±0.2)×10−21 s
Decays into
η
 :

γ
+
γ
or

π0
+
π0
+
π0
or


π+
+
π0
+
π


η′
 :

π+
+
π
+
η
or

(
ρ0
+
γ
) / (
π+
+
π
+
γ
) or


π0
+
π0
+
γ
Electric chargee
SpinInteger

The eta (
η
) and eta prime meson (
η′
) are mesons made of a mixture of up, down and strange quarks and their antiquarks. The charmed eta meson (
η
c
) and bottom eta meson (
η
b
) are forms of quarkonium; they have the same spin and parity as the light[clarification needed] eta but are made of charm quarks and bottom quarks respectively. The top quark is too heavy to form a similar meson, due to its very fast decay.[clarification needed]

General

The eta was discovered in pionnucleon collisions at the Bevatron in 1961 by A. Pevsner et al. at a time when the proposal of the Eightfold Way was leading to predictions and discoveries of new particles from symmetry considerations.[2]

The difference between the mass of the
η
and that of the
η′
is larger than the quark model can naturally explain. This "η–η′ puzzle" can be resolved[3][4][5] by the 't Hooft instanton mechanism,[6] whose 1/N realization is also known as the Witten–Veneziano mechanism.[7][8] Specifically, in QCD, the higher mass of the η' is very significant, since it is associated with the axial UA(1) classical symmetry, which is explicitly broken through the chiral anomaly upon quantization; thus its mass is not "protected" to be small, like that of the η.

Quark composition

The
η
particles belong to the "pseudo-scalar" nonet of mesons which have spin J = 0 and negative parity,[9][10] and
η
and
η′
have zero total isospin, I, and zero strangeness and hypercharge. Each quark which appears in an
η
particle is accompanied by its antiquark (the particle overall is "flavourless") and all the main quantum numbers are zero.

The basic SU(3) symmetry theory of quarks for the three lightest quarks, which only takes into account the strong force, predicts corresponding particles

, and
.

The subscripts refer to the fact that η1 belongs to a singlet (which is fully antisymmetrical) and η8 is part of an octet. However in this case the weak and electromagnetic forces, which can transform one flavour of quark into another, cause a significant, though small, amount of "mixing" of the eigenstates (with mixing angle θP = −11.5°),[11] so that the actual quark composition is a linear combination of these formulae. That is:

.

The unsubscripted name
η
refers to the real particle which is actually observed and which is close to the η8. The
η′
is the observed particle close to η1.[10]

The
η
and
η′
particles are closely related to the better-known neutral pion
π0
, where

.

In fact,
π0
, η1 and η8 are three mutually orthogonal linear combinations of the quark pairs
u

u
,
d

d
and
s

s
; they are at the centre of the pseudo-scalar nonet of mesons[9][10] with all the main quantum numbers equal to zero.

η′ meson

The η' meson (
η′
) is essentially a different superposition of the same quarks as the eta meson (
η
), the only significant differences being a higher mass, a different decay state, and a shorter lifetime.

See also

References

  1. ^ a b Light Unflavored Mesons as appearing in Olive, K. A.; et al. (PDG) (2014). "Review of Particle Physics". Chinese Physics C. 38: 090001.
  2. ^ Kupść, A. (2007). "What is interesting in
    η
    and
    η′
    Meson Decays?". AIP Conference Proceedings. 950: 165–179. arXiv:0709.0603. Bibcode:2007AIPC..950..165K. doi:10.1063/1.2819029.
  3. ^ Del Debbio, L.; Giusti, L.; Pica, C. (2005). "Topological Susceptibility in SU(3) Gauge Theory". Physical Review Letters. 94 (3): 032003. arXiv:hep-th/0407052. Bibcode:2005PhRvL..94c2003D. doi:10.1103/PhysRevLett.94.032003.
  4. ^ Lüscher, M.; Palombi, F. (2010). "Universality of the topological susceptibility in the SU(3) gauge theory". Journal of High Energy Physics. 2010 (9): 110. arXiv:1008.0732. Bibcode:2010JHEP...09..110L. doi:10.1007/JHEP09(2010)110.
  5. ^ Cè, M.; Consonni, C.; Engel, G.; Giusti, L. (2014). Testing the Witten–Veneziano mechanism with the Yang–Mills gradient flow on the lattice. 32nd International Symposium on Lattice Field Theory. arXiv:1410.8358.
  6. ^ 't Hooft, G. (1976). "Symmetry Breaking through Bell-Jackiw Anomalies". Physical Review Letters. 37 (1): 8–11. Bibcode:1976PhRvL..37....8T. doi:10.1103/PhysRevLett.37.8.
  7. ^ Witten, E. (1979). "Current algebra theorems for the U(1) "Goldstone boson"". Nuclear Physics B. 156 (2): 269–283. Bibcode:1979NuPhB.156..269W. doi:10.1016/0550-3213(79)90031-2.
  8. ^ Veneziano, G. (1979). "U(1) without instantons". Nuclear Physics B. 159 (1–2): 213–224. Bibcode:1979NuPhB.159..213V. doi:10.1016/0550-3213(79)90332-8.
  9. ^ a b The Wikipedia meson article describes the SU(3) pseudo-scalar nonet of mesons including
    η
    and
    η′
    .
  10. ^ a b c Jones, H. F. (1998). Groups, Representations and Physics. IOP Publishing. ISBN 0-7503-0504-5. Page 150 describes the SU(3) pseudo-scalar nonet of mesons including
    η
    and
    η′
    . Page 154 defines η1 and η8 and explains the mixing (leading to
    η
    and
    η′
    ).
  11. ^ Quark Model Review as appearing in Beringer, J.; et al. (PDG) (2012). "Review of Particle Physics" (PDF). Physical Review D. 86 (1): 010001. Bibcode:2012PhRvD..86a0001B. doi:10.1103/PhysRevD.86.010001.