The masses of heavy pentaquarks in the non-relativistic Bethe-Salpeter quark model

Abu-Shady, M.; Gerish, N. H.; Ahmed, M. M. A.; Abu-Shady, M.; Gerish, N. H.; Ahmed, M. M. A.

doi:10.31349/revmexfis.68.010801

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Revista mexicana de física

versión impresa ISSN 0035-001X

Rev. mex. fis. vol.68 no.1 México ene./feb. 2022 Epub 23-Jun-2023

https://doi.org/10.31349/revmexfis.68.010801

Research

High Energy physics

The masses of heavy pentaquarks in the non-relativistic Bethe-Salpeter quark model

M. Abu-Shady^a

N. H. Gerish^b

M. M. A. Ahmed^c

^{^a} Department of Mathematics and Computer Science, Faculty of Science, Menoufia University, Egypt.

^{^b} Department of Mathematics and Computer Science, Faculty of Science, Suez Canal University, Egypt.

^{^c} Department of Mathematics and Computer Science, Faculty of Science, Al-Azhar University, Egypt.

Abstract

The exotic particles such as the pentaquarks are believed to strengthen the understanding of important interactions and the principle of QCD in which pentaquarks contain two heavy-valence quarks. The structure of two bodies including an antiquark and two-diquark is introduced. A new potential for quark interaction is suggested which includes the logarithm and linear potentials, as well as the spin-spin interaction. The suggested potential is included in the framework of spinless of the Bethe-Salpeter equation. A comparison with other works is presented which provides a good description of pentaquarks.

Keywords: Pentaquarks; antiquark; two-diquark

1 Introduction

Mesons and baryons (and so multiquark states) can be described by QCD models, in a medium ^[¹^-⁸^]. Diquark interactions appear to play an important role in hadron physics, according to QCD ^[⁹^], the only requirement for these states is to be color singlets. The quark model was suggested by Murray Gell-Mann and George Zweig in their papers in 1964 since exotic hadrons such as pentaquarks were discussed ^[¹⁰^]. While most ground-state mesons and baryons are experimentally well defined, several recently observed states are under debate because their quark content and/or spin/parity are unknown; see ^[¹¹^-¹⁵^] for a study on possible exotic states. Previously, exotic particles like X(3872) and Z_c have been investigated by scientists ^[¹⁶^]. The decay of Z_c into J/ψ (a bound state of charm-anticharm quarks) revealed that this particle was made up of two quarks and two antiquarks. The tetraquark as a bound state is supporting the existence of five-quark states called pentaquarks^[¹⁷^,¹⁸^].

The authors ^[¹⁹^,²⁰^] study the spectra of tetraquarks and present the fully charmed tetraquark decay width. The physics of pentaquarks has recently improved in this regard, with the LHCb Collaboration reporting three heavy pentaquarks, P_c’s. An experimental observation of heavy pentaquarks containing charm or bottom quarks has also been looked into ^[²¹^].

The binding mechanism associated with exotic states is still unclear. Various interpretations can be assigned according to the following three types of models. (i) The meson-baryon molecular model or their mixture. For this model, the energy spectrum has been evaluated using a chiral effective Lagrangian approach, the QCD sum rules, the color-screen model, and the scattering amplitudes approach. (ii) Diquark (triquark) interaction models, for which the diquark-diquark-antiquark model and compact diquark-triquark model have been used; see ^[²²^] and references therein. In addition, a classification of all possible pentaquark states QQqqq- depend on the corresponding quantum numbers and mass predictions have been presented ^[²³^,²⁴^].

The LHCb collaboration reported ^[²⁵^] the observation of a narrow pentaquark state, P_c(4312)⁺ a decay of J/ψ with the statistical significance of 7.3σ in a data sample of Λb0→J/ψ+p+K- decays, one order of magnitude higher than the previous collaboration study at the LHCb ^[²⁶^]. The pentaquark structure of P_c(4450)⁺ previously presented by LHCb, is also observed and reported ^[²⁵^,²⁷^] to consist of two main small overlapping peaks, P_c(4440)⁺ and P_c(4457)⁺ where this two-peak representation has a statistical significance of 5.4σ. Until now, for the features of pentaquarks, many various schemes have been suggested. For example ^[²⁸^], two interpolating currents are used in a diquark-diquark-antiquark description of pentaquarks to measure the mass of the E^{— —} state in the form of the QCD sum rules. With the perturbative chiral quark model ^[²⁹^], the mass spectra of J^p = 3/2 pentaquarks were examined. In Ref.^[³⁰^], the authors calculated pentaquark masses by a changed mass formula adapted to the masses of baryons. In a constituent quark model with a full description of qqqqq- pentaquark states, some properties of qqqqq- pentaquark states, like their masses and magnetic moments, were acquired ^[³¹^]. Karliner and Lipkin ^[³²^]. proposed a formula to estimate their masses for pentaquark states. The diquark-triquark model was applied to clarify charmonium-pentaquark states ^[²²^]. The important characteristics are based on the antiquark-diquark-diquark scheme, that correlates to the experimental evidence obtained ^[³³^]. The QQqqq- pentaquarks were studied in a potential model, based on the hypothesis that they are composite particles containing two diquarks and one antiquark with a Cornell potential as VCornell=(-a/r)+br+c^[³⁴^]. The same potential was used in Ref. ^[³⁵^] but the authors developed the pentaquark model using multiple hypotheses.

In this study, we determine the masses of pentaquarks in the ground state, considering that a pentaquark is a bound state of two diquarks and an antiquark. The physical theory behind the description of the diquark is the union to combine any two quarks into a colored quasi-bound state. This approach makes it possible, firstly, to discuss the idea of using the diquark principle in this case. Secondly, to calculate more brief details for the masses, expressions. We used the Bethe-Salpeter equation with the potential energy of quark interaction given by logarithm, lienar, and spindependent potentials. To the best of our knowledge, the logarithm potential has not been used to calculate the masses of pentaquarks. Our numerical results for the ground masses for the various pentaquarks models with spin (1/2)^— , (3/2)^— are (5/2)^— provided. Our observations can be correlated with the outcomes of other studies, such as ^[³⁴^,³⁵^].

The paper is arranged as follows: in Sec. 2, the Bethe-Salpeter equation is resolved in the present potential. In Sec. 3, the numerical results and discussion are shown. In Sec. 4, the conclusion is presented.

2 The Theoretical Model

To research two heavy pentaquarks, we assume them to be the bound state of two heavy diquarks and antiquarks. As a result, the Bethe-Salpeter equation in QCD can be used to describe this two-body structure. The well-known Beth-Salpeter equation is obtained by considering the natural units (where h-=c=1) ^[³⁵^],

p2+m12)12+p2+m2212+Vrψnlr=Mψnlr, (1)

where m1 and m2 describe the masses of the two-body structure components, V(r) is the quark-antiquark potential, M is the mass of the bound state and ψ denotes the wave function. A convenient solution to avoid interacting with the kinetic energy operator’s non-local character in Eq. (1) is to extend it, as in ^[³⁶^] for heavy interacting particles at p < μ,

(p2+m12)12+(p2+m22)12=m1+m2+p22μ-p28αμ3+… (2)

where the reduced mass μ is

μ=m1m2m1+m2

and

α=m1m2m1m2-3μ2.

We only take terms up to order 1/μ³ in the above equation; this is a strong approximation for heavy interacting particles and uses the operator p2=-∇2 and p4=4μ2[E-Vr]2, where the energy of the bound state is E=M-m1-m2, it with which it is possible to rewrite Eq. (1) in

{-12μd2dr2+2rddr-l(l-1)r2+V(r)+m1+m2-[M-m1-m2-V(r)]22αμ}ψnl(r)=Mψnl(r). (3)

The potential used in Eq. (3) for each two-body interaction contains the logarithm and linear potentials with a spin-spin interaction as

V(r)=Vlog(r)+Vspin(r), (4)

Vlog(r)=ar+blogrr0, (5)

Vspin(r)=ηe-σ2r2,η=Aσ3S1.S22π3/2m1m2 (6)

The parameter here specifies the function of the smeared delta for that we follow σ =1.209 GeV ^[³⁴^] and r₀ = 7.959 GeV^{-1 [}³⁷^]. In the one gluon exchange approximation, the parameter A is related to the strong constant coupling αs.

S₁ and S₂ are the spins of the interacting particles in the spin-spin interaction, where: S1⋅S2=(1/2)[S(S+1)-S1(S1+1)-S2(S2+1)], and S is the total spin.

Two contributions are usually included in the interaction potential of two colored objects. One of them is based on the qq- potential determined in the gauge/string duality technique in QCD, and another concept defines the interaction between spin-spin. Color interaction describes this potential that is determined by a virtual model inspired by Cornell potential presented in Ref. ^[³⁴^] and that it has been replaced the logarithmic potential in present work as in Eq. (5). A comparison between both potentials is shown in Fig. 1, where it is clear that one has the same behavor for the two potentials.

Figure 1 A comparison between the Cornell ^[³⁵^] and logarithm potentials.

By introducing ψnl(r)=X(r)r-1 and using the potential in Eq. (4), then Eq. (3) can defined as;

-d2Xdr2+l[l-1]r2-V2(r)α+V(r)2(M-m1-m2)α+2μ-[M-m1-m2]2α+2μ(-M+m1+m2)}X(r)=0 (7)

Taking into account that r < 1 fm, we apply the simple approximation to analytically solve the above equation. Approximating e-σ2r2≈1-σ2r2+… and log[r/r0]≈-(3/2)+(2/r0)r-(1/2r02)r2+… leading to a potential parametrized by

V(r)=a1+a2r+a3r2, (8)

where

a1=-3b2+η,a2=a+2br0,a3=-b2r02-ησ2, (9)

with which Eq. (7) becomes

d2X(r)dr2≈ζ1r4+ζ2r3+ζ3r2+ζ4r+ζ5+ζ6r2X(r), (10)

where

ζ1=-a32α,ζ2=-2a2a3α,ζ3=-a22+2a1a3α+a32[M-m1-m2]α+2μ,ζ4=-2a1a2α+a22[M-m1-m2]α+2μ,ζ5=-a12α+a12[M-m1-m2]α+2μ,ζ6=l(l-1). (11)

Equation (10) cannot be solved analytically yet, so the following method suggested ^[³⁸^] is used in which we describe

Xnl(r)=Ω(r)eϕ(r), (12)

where

ϕ(r)=t0+t1r2+t2r3+t3ln[r], (13)

X''r=9t22r4+12t1t2r3+4t12r2+6t2t3+6t2r+4t1t3+2t1+t32-t31r2Xr, (14)

With

t1=±ζ32,t2=±ζ13, (15)

t3=ζ42ζ1-1, (16)

we then get

ζ5=±ζ3{±ζ4ζ1-1}. (17)

We solve Eqs. (15)-(17) with Eq. (11), where we have used the masses of quark as m_u = m_d = 0.302 GeV, m_c = 1.733 GeV, m_s = 0.454 GeV, m_b = 5.139 GeV, A_c = 7.920 and A_b = 3.087 ^[³⁵^]. We calculate the diquark masses as shown in Table 1, the following notation is assumed to be: [Qq] diquark has spin 0, and {Qq} for spin 1.

Table I The diquark masses (in GeV).

Diquark	M (this work)	M^[³⁴]	M^[³⁵]
[bu]_s=0	5.24	5.513	5.29
{bu}_s=1	5.55	5.53	5.438
[bs]_s=0	5.56	5.62	5.411
{bs}_s=1	5.59	5.63	5.572
[cu]_s=0	2.16	2.118	1.904
{cu}_s=1	2.45	2.168	2.322
[cs]_s=0	2.56	2.23	1.966
{cs}_s=1	2.6	2.37	2.442

3 Numerical results and discussion

It’s worth noting that the one-gluon-exchange approximation and the use of an instantaneous potential can only be extended to heavy states in which at least one of the two interacting particles is heavy, containing a charm or bottom quark. As a result, we calculate the masses of pentaquarks with at least one heavy quark. Furthermore, we only consider states with orbital angular momentum at each state l = 0

The masses of pentaquarks in the ground state are calculated using the hypothesis that a pentaquark is a bound state of two diquarks and an antiquark. The union of any two quarks to form a colored quasi-bound state is the physical theory behind the diquark’s explanation. This method allows us to first explore the concept of applying the diquark theory in this situation. Second, to obtain more concise information for the masses expressions. By including the logarithm, linear and the spin-dependent potentials, we solve the Bethe-Salpeter equation of quark interaction. Using the relationship between logarithmic potential and the Cornell potential ^[³⁵^]VCornell=-ar+br+c, we get a = 0.14 GeV and b = 0.342 GeV² as the parameters of present potential. We present our numerical results for ground state masses for the pentaquarks model stated in Fig. 2 and with spin (1/2)^— (3/2)^— and (5/2)^—.

Figure 2 The form of pentaquark QqQqq-.

The masses of pentaquarks with two heavy diquarks are determined, with each diquark having one light quark and one heavy quark, as shown in Fig. 2. We measure heavy diquark masses using the Bethe-Salpeter Eq. (3) for a diquark-diquark system with the considering potential, and then the mass of heavy pentaquarks at ((1/2)^— (3/2)^— and (5/2)^—) spin resulting from the four-quark state-to-one antiquark interaction. Where m₁ and m₂ are the masses of two diquarks and antiquark, and M is the pentaquark mass. The masses of pentaquarks are shown in Tables II, III, and IV, with l = 0 set and our results compared to Refs. ^[³⁴^,³⁵^]; notice that all states have negative parity. Other pentaquark masses with the same model but different antiquarks (charm quark or bottom quark) are mentioned in Tables V, VI, and VII.

Table II The masses of pentaquarks at J^p = (1=2)^— in GeV.

Pentaqurk	M (this work)	M^[³⁴]	M^[³⁵]
[bu]_s=1[bu]_s=0u-	11.12	11.19	11.17
[bs]_s=1[bu]_s=0u-	11.15	11.28	11.16
[bs]_s=0[bu]_s=1u-	11.44	11.28	11.29
[cu]_s=0[cu]_s=1u-	4.21	4.64	4.33
[cs]_s=1[cu]_s=0u-	4.38	4.73	4.4
[cs]_s=0[cu]_s=1u-	4.67	4.73	4.64
[bu]_s=0[cu]_s=1u-	7.9	7.94	7.67
[bu]_s=1[cu]_s=0u-	7.91	7.94	7.60
[bu]_s=0[cs]_s=1u-	8.06	8.04	7.80
[bu]_s=1[cs]_s=0u-	8.33	8.04	7.76

Table III The masses of pentaquarks at J^p = (3/2)^— in GeV.

Pentaqurk	M (this work)	M^[³⁴]	M^[³⁵]
[bu]_s=1[bu]_s=1u-	11.24	11.18	11.47
[bs]_s=1[bu]_s=1u-	11.28	11.27	11.60
[bu]_s=0 [bu]_s=1u-	11.47	11.21	11.32
[bs]_s =1 [bu]_s=0u-	11.49	11.30	11.45
[bs]_s=0 [bu]_s=1u-	11.78	11.30	11.44
[cs]_s =1 [cu]_s=1u-	5.35	4.72	4.81
[cu]_s=1[cu]_s=1u-	5.45	4.62	4.76
[cu]_s=0[cu]_s=1u-	5.58	4.72	4.87
[cs]_s=1 [cu]_s=0u-	5.72	4.82	4.98
[cs]_s=0 [cu]_s=1u-	5.95	4.82	4.87
[bu]_s=0[cu]_s=1u-	8.29	7.97	8.23
[bu]_s=1[cu]_s=0u-	8.299	7.97	7.76
[bu]_s=1[cu]_s=1u-	8.45	7.97	8.37
[bu]_s=0[cs]_s=1u-	8.46	8.06	8.34
[bu]_s=1[cs]_s=0u-	8.56	8.06	7.92
[bu]_s=1[cs]_s=1u-	8.63	8.03	8.49

Table IV The masses of pentaquarks at J^p = (5/2)^— in GeV.

Pentaqurk	M (this work)	M^[³⁴]	M^[³⁵]
[bu]_s=1[bu]_s=1u-	11.18	11.22	11.69
[bs]_s=1[bu]_s=1u-	11.21	11.31	11.74
[cs]_s=1 [cu]_s=1u-	4.77	4.85	4.98
[cu]_s=1[cu]_s=1u-	4.85	4.75	4.87
[bu]_s=1[cu]_s=1u-	8.73	7.98	8.1
[bu]_s=1[cs]_s=1u-	8.94	8.07	8.64

Table V The masses of pentaquarks at J^p = (1/2)^— considering q-=c- or b- in GeV.

Pentaquark	M (this work)	Pentaquark	M (this work)
[cu]_s=1[cu]_s=0c-	7.17	[cu]_s=1[cu]_s=0b-	10.65
[cu]_s=0[cs]_s=1c-	7.31	[cu]_s=0[cs]_s=1b-	10.803
[cu]_s=1[cs]_s=0c-	7.56	[cu]_s=1[cs]_s=0b-	11.06
[cs]_s=1[cs]_s=0c-	7.72	[cs]_s=1[cs]_s=0b-	11.21
[cu]_s=1[bu]_s=0c-	10.21	[cu]_s=1[bu]_s=0b-	13.72
[cu]_s=0[bu]_s=1c-	10.22	[cu]_s=0[bu]_s=1b-	13.73
[cs]_s=0[bs]_s=1c-	10.64	[cs]_s=0[bs]_s=1b-	14.15
[cs]_s=1[bs]_s=0c-	10.65	[cs]_s=1[bs]_s=0b-	14.16
[bu]_s=1[bu]_s=0c-	13.33	[bu]_s=1[bu]_s=0b-	16.86
[bs]_s=1[bs]_s=0c-	13.67	[bs]_s=1[bs]_s=0b-	17.2

Table VI The masses of pentaquarks at J^p = (3/2)^— considering q-=c- or b- in GeV.

Pentaqurk	M (this work)	Pentaquark	M (this work)
[cu]_s=1[cu]_s=0c-	7.12	[cu]_s=1[cu]_s=0b-	10.61
[cu]_s=0[cs]_s=1c-	7.27	[cu]_s=0[cs]_s=1b-	10.76
[cu]_s=1[cs]_s=1c-	7.49	[cu]_s=1[cs]_s=1b-	10.99
[cu]_s=1[cs]_s=0c-	7.52	[cu]_s=1[cs]_s=0b-	11.02
[cu]_s=1[cu]_s=1c-	7.597	[cu]_s=1[cu]_s=1b-	11.09
[cs]_s=1[cs]_s=1c-	7.66	[cs]_s=1[cs]_s=1b-	11.15
[cu]_s=1[cs]_s=0c-	7.67	[cu]_s=1[cs]_s=0b-	11.18
[cu]_s=1[bu]_s=0c-	10.202	[cu]_s=1[bu]_s=0b-	13.71
[cu]_s=0[bu]_s=1c-	10.206	[cu]_s=0[bu]_s=1b-	13.72
[cu]_s=1[bu]_s=1c-	10.49	[cu]_s=1[bu]_s=1b-	14.01
[cs]_s=1[bs]_s=1c-	10.59	[cs]_s=1[bs]_s=1b-	14.11
[cs]_s=0[bs]_s=1c-	10.63	[cs]_s=0[bs]_s=1b-	14.14
[cs]_s=1[bs]_s=0c-	10.64	[cs]_s=1[bs]_s=0b-	14.15
[bu]_s=1[bu]_s=0c-	13.34	[bu]_s=1[bu]_s=0b-	16.86
[bu]_s=1[bu]_s=1c-	13.34	[bu]_s=1[bu]_s=1b-	16.86
[bs]_s=1[bs]_s=1c-	13.66	[bs]_s=1[bs]_s=1b-	17.18
[bs]_s=1[bs]_s=0c-	13.68	[bs]_s=1[bs]_s=0b-	17.2

Table VII The masses of pentaquarks at J^p = (5/2)^— considering q-=c- or b- in GeV.

Pentaqurk	M (this work)	Pentaquark	M (this work)
[bs]_s=1[bs]_s=1c-	13.33	[bs]_s=1[bs]_s=1b-	16.85
[bu]_s=1[bu]_s=1c-	13.65	[bu]_s=1[bu]_s=1b-	17.17
[bs]_s =1 [cs]_s=1c-	10.57	[bs]_s=1[cs]_s=1b-	14.08
[bu]_s⁼¹[cu]_s=1c-	10.47	[bu]_s=1[cu]_s=1b-	13.98
[cu]_s⁼¹[cu]_s=1c-	7.51	[cu]_s=1[cu]_s=1b-	11.02
[cs]_s⁼¹[cs]_s=1c-	7.57	[cs]_s=1[cs]_s=1b-	11.08

Table II shows the pentaquark masses with the spin (1/2)^— and negative parity, based on the results of Table I. The same results are reported in Table III, but for pentaquarks with the spin (3/2)^— . Table IV also contains the results for the spin (5/2)^— pentaquarks. Pentaquarks with spin (1/2)^— have masses ranging from 4.21 to 11.44 GeV, while those with spin (3/2)^— and (5/2)^— have masses ranging from 5.35 to 11.78 and 4.77 to 11.21 GeV, respectively.

4 Conclusion

We used the Bethe-Salpeter equation to describe pentaquark which contains two heavy-valence quarks within the present potential, which includes logarithm and linear potentials with a spin-spin interaction. As shown in Fig. 2, the method involves computing diquark masses from interactions between single quarks, followed by the four-quark state mass formed by two diquarks, and finally the pentaquark mass resulting from the four-quark state mass with an antiquark. Our pentaquark masses are mentioned in Tables II, III, IV, V, VI, and VII with spin ((1/2)^— (3/2)^— and (5/2)^—). In comparison to other recent works, the present potential produces compatible results with other potential models.

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Received: May 01, 2021; Accepted: July 05, 2021

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Revista mexicana de física

versión impresa ISSN 0035-001X

Rev. mex. fis. vol.68 no.1 México ene./feb. 2022 Epub 23-Jun-2023

https://doi.org/10.31349/revmexfis.68.010801