I. The discovery of d* dibaryon 1964 F.J. Dyson and N.H. Xuong predicted a D03(IJP=03+) 6-quark state at 2.35 GeV based on M.Gell-Mann quark model. PRL 13(1964) we predicted the IJP=03+ is an inevitable dibaryon resonance and named it as d*. T. Goldman, et al. PRC39(1989) we extended the Feshbach resonance to NN and channel coupling and obtained the right resonance mass and partial width, strongly supported WASA-at-COSY experimental search of d* dibaryon. J.L. Ping et al, arxiv: [nucl-th], PRC79(2009)
The d* dibaryon structure and the hidden color channel effect
Jia-lun Ping, Hong-xia Huang Dept. of Physics, Nanjing Normal
University Fan Wang Dept. of Physics, Nanjing University Outline
I.The Discovery of d* dibaryon II.The hidden color components
explanation of the small width of d* III.The classification of
6-quark states IV.The d* structure V.summary I. The discovery of d*
dibaryon 1964 F.J. Dyson and N.H. Xuong predicted a D03(IJP=03+)
6-quark state at 2.35 GeV based on M.Gell-Mann quark model. PRL
13(1964) we predicted the IJP=03+ is an inevitable dibaryon
resonance and named it as d*. T. Goldman, et al. PRC39(1989) we
extended the Feshbach resonance to NN and channel coupling and
obtained the right resonance mass and partial width, strongly
supported WASA-at-COSY experimental search of d* dibaryon. J.L.
Ping et al, arxiv: [nucl-th], PRC79(2009) 2011 WASA-at-COSY found
evidence of the d* exotics M. Bashkanov et al., arxiv: [nucl-ex];
[nucl-ex]; PRL 102(2009)052301;106(2011)242302; CERN Courier 2011,
Aug WASA-at-COSY confirmed the existence of the d* six-quark state.
P. Adlarson et al, arXiv: [nucl-es];PRL 112(2014)202301; CERN
Courier 2014, July 23. II.The hidden color components explanation
of the small width of d* dibaryon The observed width (~80 MeV) of
the d* dibaryon is much smaller than the two width (~240 MeV) even
after taking into account the reduction due to (~84 MeV) binding,
our theoretical estimate based on the nave phase space reduction is
~110 MeV (PRC79(2009)024001). A popular explanation of the small
width of the d* dibaryon is attributed to the hidden color
components of d*: M. Bashkanov, S.J. Brodsky, H. Clement, Phys.
Lett. B727(2013)438; arXiv: [hep-ph]. F. Huang, et al., Chin. Phys.
C39(2015)7, Y.B. Dong, et al. Phys. Rev. C91(2015)6, Different
interpretation of the hidden color component effect There are two
independent components of d* within the limited two baryon Hilbert
space, i.e., the d* consists of two orbital ground state baryons.
One is the colorless, the other is a hidden color component. F.
Huang and Y.B. Dong both assume that the hidden color channel
component dominates the d* structure and it does not decay at all.
BBC also assume the hidden color channel component is the dominant
one but it decays through. III.The classification of 6-quark states
Nuclear physics employed both group chain classification wave
functions and cluster wave functions for multi-body systems. They
are also called symmetry bases and physical bases. We use color
singlet quark cluster wave functions to study the NN interaction
and add hidden color quark cluster wave functions to study the
color van der Waals force in the beginning of 1980s. F. Wang, Y.
He, Chinese Nucl. Phys. 2(1980)261; 4(1982)176; in Contributed
papers of the workshop from collective states to quark in nuclei,
p.2, Bologna, Italy, Nov , 1980. M. Harvey introduced the
transformation between physical and symmetry bases. Nucl. Phys.
A352(1981) For the 6-quark cluster wave function one mainly
interested in those ones where every three quarks form a ground
state baryon, i.e., three quarks occupy the same lowest orbital
state (s-wave state). Two baryons located in two different centers,
the left one has the left centered s wave l, the right one has the
right centered s wave r. The overlap is between 1 and 0 depends on
the separation x of the two centers. Only in the infinite
separation limit the ->0, i.e., mutual orthogonal. Under the
totally orbital symmetry assumption [3] of the individual baryon,
the orbital symmetry of 6-quark system is limited to The parity of
the first two are positive and the second two are negative. Because
of the non-orthogonality of l and r orbit, only the totally
symmetry [6] survives as a state in the x->0 limit. In order to
keep all of the four symmetry bases normalized in any separation x,
Harvey nomalized every symmetry basis with a nomalization factor
N([f]). In the x- >0 limit, the four orbital symmetry bases have
the following limit. [6]-> [42]-> [51]-> [33]-> Harveys
cluster bases are mutual orthogonal, but not easy to use in quark
model calculation. The usual cluster wave functions are easier to
be used in quark cluster model calculations and so they are the
commonly used ones. These cluster wave functions (after anti
symmetry) are not mutual orthogonal because the individual quark
orbital wave function l and r are not orthogonal. Based on these
cluster bases to count how much percentage of hidden color
component within d* is meaningless. In the cluster separation
x->0 limit, only the [6] symmetry basis survives (to be a
state), all the other symmetry states disappear. In the x->
limit, to claim the [6] symmetry state is still a mixture of
colorless and hidden color channel is meaningless because there is
only one state [6] survives for the IS=03 channel. The colorless
and hidden color anti-symmetry cluster bases collapse to one state.
Harvey used the group chain classified symmetry bases to express
the colorless channels, but used another group chain classified
symmetry bases to express the hidden color channels. J.Q. Chen et
al. remedied this drawback and developed a systematic method to
calculate the transformation coefficients between symmetry and
cluster bases. For deuteron channel they obtained 5 hidden color
channels and two colorless channels. J.Q. Chen et al., Nucl. Phys.
A393(1983) The symmetry bases and the cluster bases (including both
colorless and hidden color channels) are equivalent and both can be
used to diagonalize the Hamiltonian of the multi-quark systems. In
fact we can also use solely the colorless or hidden color channels
if one allows the orbital excited hadron clusters, because one can
transform the hidden color channels to colorless channels and vice
versa via the quark exchange. D. Robson, Prog. Part. Nucl. Phys.,
8(1982)257; F. Wang, C.W. Wong, Nuovo Cimento, 86A(1985)283; F.
Wang, Chinese Prog. Phys., 9(1989)297. For color SU(3), the
dimension of irreps [222] =1 For S(6), the dimension of irreps
[222] =5 Constructing the bases of 6-quark system from two
three-quark clusters Outer-product of S(6) 5 bases of [222]
[111]x[111] (color singlet) color singlets are enough! IV.The d*
structure The d* should be the lowest state with quantum number
IS=03 obtained from the diagonalization of the 6-quark Hamiltonian.
We diagonalized two quark model Hamiltonian within the two channel
space, one colorless and one hidden color channel, to obtain the
eigen- states. For Harveys two cluster bases our result is almost a
half-half mixing. c1: color-singlet c8: color-octet x (fm) E1(MeV)
c12 c82 E2(MeV) c12 c For the usual cluster bases, the mixing
coefficients are not the probability amplitude. To obtain the
probability amplitude one has to orthonomalize the cluster channel
wave function. We first diagonalize the 6-quark model Hamiltonian
with the two anti-symmetric cluster wave function, obtain the
ground state d* eigen-function, then calculate the overlap between
the anti-symmetric colorless and hidden color channel wave
function, then define the hidden color component as. We admit this
is just one possible definition of an orthogonal component and we
take it as the hidden color channel wave function. Under this
definition of hidden color channel, our result has quite small
hidden color component for the ground state. x (fm) E1(MeV) c1 2 c8
2 E2(MeV) c1 2 c At least our two results show that how much hidden
color component within the d* is model dependent. To use the two
quark cluster channel wave functions as the bases limit the Hilbert
space of the multi-quark systems. We found this limitation can not
be a good approximation when two baryon very close together even
for the loosely bound deuteron d. F. Wang et al., Phys. Rev. Lett.,
69(1992)2901. d* is a tightly bound system, its rms radius is about
1fm, binding energy is 84 MeV, so we relax this limitation by
allowing different quark clustering components, i.e., in addition
to the 3,3 quark cluster we add 4,2; 5,1; 6,0 clusters and found
all of these configurations does exist in the d*. We also do a
6-body calculation without assuming any clustering and this
calculation is on going. V. Summary d* is compact deep bound six
quark state, two baryon clustering is a crude approximation. Up to
now the hidden color channel wave function is just a coupling
scheme, the hidden color component effect of d* is model dependent.
With the two baryon clustering approximation of d* structure, the
d* is always a mixing of the hidden color component and the
colorless channel. The percentage of hidden color component is
dependent on the definition. The colorless component directly decay
but with a phase space reduction. The hidden color channel also
decay to through the channel coupling.
