Light D wave meson spectrum in a relativistic harmonic model with instanton induced interaction

doi:10.4236/ns.2010.211156

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Vol.2, No.11, 1292-1297 (2010) Natural Science

http://dx.doi.org/10.4236/ns.2010.211156

Light D wave meson spectrum in a relativistic harmonic

model with instanton induced interaction

Antony Prakash Monteiro, Kanti Basavarajappa Vijaya Kumar*

Department of Physics, Mangalore University, Mangalagangothri, Mangalore, India; *Corresponding author: kbvijaya kumar@

yahoo.com

Received 20 July 2010; revised 25 August 2010; accepted 28 August 2010.

ABSTRACT

The mass spectrum of the D wave mesons is

considered in the frame work of relativistic

harmonic model (RHM). The full Hamiltonian

used in the investigation has the Lorentz scalar

plus a vector harmonic-oscillator potential, the

confined-one-gluon-exchange potential (COGEP)

and the instanton-induced quark-antiquark in-

teraction (III). A good agreement between calcu-

lated D wave meson masses with experimental

D wave meson masses is obtained. The respec-

tive role of III and COGEP in the D wave meson

spectrum is discussed.

Keywords: Quark Model; Confined-One-Gluon-

Exchange Potential; Instanton Induced Interaction;

D Wave Meson Spectra

1. INTRODUCTION

The Quantum Chromodynamics (QCD), the theory of

strong interactions, is not exactly solvable in the

non-perturbative regime which is required to obtain the

physical properties of the hadrons. Hence various ap-

proximation methods like lattice gauge theories are em-

ployed to solve QCD in the non-perturbative regime. In

the constituent quark model, conventional mesons are

bound states of a spin ½ quark and spin ½ antiquark

bound by a phenomenological potential. The phenome-

nological models developed to explain the observed

properties of mesons are either non-relativistic quark

models (NRQM) with suitably chosen potential or rela-

tivistic models where the interaction is treated pertur-

batively [1-3]. In most of the works that use NRQM, it is

assumed that the quark interaction is dominated by a

linear or quadratic confinement potential and is supple-

mented by a short range potential stemming from the

one-gluon exchange mechanism. The Hamiltonian of

these quark models usually contains three main ingredi-

ents: the kinetic energy, the confinement potential and a

hyperfine interaction term, which has often been taken

as an effective one-gluon-exchange potential (OGEP) [4].

Other types of hyperfine interaction like Instanton-

Induced Interaction (III) deduced by a non-relativistic

reduction of the ‘t Hooft interaction [5-12] have also

been introduced in the literature.

The success of the NRQM in describing the hadron

spectrum is somewhat paradoxical, as light quarks

should in principle not obey a non-relativistic dynamics.

This paradox has been avoided in many works based on

the constituent quark models by using for the kinetic

energy term of the Hamiltonian a semi-relativistic or

relativistic expression [9-12]. Even in the existing rela-

tivistic models though the effect of confinement of

quarks has been taken into account, the effect of con-

finement of gluons has not been taken into account

[13-15]. Therefore in our present work, we have inves-

tigated the effect of exchange of confinement of gluons

on the masses of light D wave mesons and their radially

excited states in the frame work of RHM with III

[6,11-12,16]. The essential new ingredient in our inves-

tigation of the light D wave mesonic states is to take into

account the confinement of gluons in addition to the

confinement of quarks. In the existing quark models,

Fermi-Breit interaction which gives rise to π- and N-

splitting is treated as perturbation. The OGEP being at-

tractive for π, and for a nucleon a naïve perturbative

treatment of one gluon hyperfine interaction is incorrect

and hence one obtains a high value for the pion mass. This

leads to further renormalization of strength of interaction

for a better fit. Also, the most prominent flaw of NRQM is

the neglect of relativistic effects and gluon dynamics. In

our present work, for the confinement of quarks we are

making use of the RHM which has been successful in

explaining the properties of light hadrons. For the con-

finement of gluons, we have made use of the current con-

finement model (CCM) which was developed in the spirit

of the RHM [13-15]. The CCM has been quite successful

in describing the glue-ball spectra. The confined gluon

A. P. Monteiro et al. / Natural Science 2 (2010) 1292-1297

1293

propagators (CGP) are derived in CCM. Using CGP we

have obtained confined one gluon exchange potential

(COGEP). The full Hamiltonian used in the investigation

has Lorentz scalar plus a vector harmonic-oscillator po-

tential, in addition to two-body COGEP and III. In our

present work we are extending the model to study D wave

light meson spectra. In our present work, the total mass of

the meson is obtained by calculating the energy eigen

values of the Hamiltonian in the harmonic oscillator basis

spanned over a space extending upto the radial quantum

number nmax = 4. The masses of D wave mesons are ob-

tained after diagonalising for various values of nma x .

In Section 2, we review the RHM and CCM models

and give a brief description of the CGP, COGEP and III.

We also discuss the parameters involved in our model.

The results of the calculations are presented in Section 3.

Conclusions are given in Section 4.

2. THE MODEL

In RHM, quarks in a hadron are confined through the

action of a Lorentz scalar plus a vector harmonic-oscilla-

tor potential [13-15].



conf

Vr ArM



 



(1)

where 0



is the Dirac matrix:











, (2)

M is the quark mass and A2 is the confinement strength.

They have a different value for each quark flavour. In

RHM, the confined single quark wave function (



) is

given by:















 

σP (3)

with the normalization



NEM



; (4)

where E is an eigenvalue of the single particle Dirac

equation with the interaction potential given in (1). The

lower component is eliminated by performing the simi-

larity transformation,







(5)

where U is given by,



NEM























 







σP

(6)

formation operator. With this transformation, the upper

component



satisfies the harmonic oscillator wave

equation.



ArE M













P (7)

which is like the three dimensional harmonic oscillator

equation with an energy-dependent parameter2





AE M (8)

The eigenvalue of (7) is given by,





22 2

21 .

EM n



 (9)

Note that Eq.7 can also be derived by eliminating the

lower component of the wave function using the

Foldy-Wouthuysen transformation as it has been done in

[13].

Adding the individual contributions of the quarks, we

obtain the total mass of the hadron. The spurious centre

of mass (CM) is corrected by using intrinsic operators for

the 2



and 2





terms appearing in the Hamilto-

nian. This amounts to just subtracting the CM motion

zero point contribution from the 2

E expression. It

should be noted that this method is exact for the 0S-state

quarks as the CM motion is also in the 0S state.

The two body quark-antiquark potential is the sum of

COGEP and III potential.









ijij ij

q COGEPIII

VrVrVr





(10)

COGEP is obtained from the scattering amplitude

[3,13-15],



42 2

ii ij j

MDq







 



 (11)

where, 0







, /ij



are the wave functions of the

quarks in the RHM, ab





 are the CCM gluon

propagators in momentum representation, 24





)

is the quark-gluon coupling constant and i



is the color

(3)c

SU generator of the th

iquark. The details can be

found in references [3,13]. Below, we list the expressions

for the central, tensor and spin-orbit part of the COGEP.

The central part of COGEP is [3,13-15],



 

342

4123

()

cent ij

COGEPi j

ijij ij

DcrD

rrr







 























σσ

λλ





(12)

To calculate the matrix elements (ME) of COGEP, we

have fitted the exact expressions of 0()Dr



and 1()Dr



by Gaussian functions. It is to be noted that the 0()Dr



and 1()Dr



are different from the usual Coulombic

propagators. However, in the asymptotic limit (0r



)

they are similar to Columbic propagators and in the in-

frared limit ()r



they fall like Gaussian. In the

A. P. Monteiro et al. / Natural Science 2 (2010) 1292-1297

1294

above expression the c (fm-1) gives the range of propaga-

tion of gluons and is fitted in CCM [13,14] to obtain the

glue ball spectra. The 0()Dr



and 1()Dr



are given by,





= r













exp









; 1()Dr



= r



exp









where 1



= 1.035994, 2



= 2.016150 fm-1, 0

c =

(3.001453)1/2 fm-1,



= 0.8639336.

And 2

c= (4.367436)1/2 fm-1.

Tensor part of COGEP is,

()

TENij

COGEP



=- 4



λλ 2

()EM







() ()

ij ij

Dr Dr













S (13)

where ij

ˆˆˆ

S[3(.)(.).]

ijiji j

rrσσ σσ

where ˆˆˆ

rrr is the unit vector in the direction of r



In the above expression primes and double primes corre-

sponds to first and second derivatives of 1()Dr



. The de-

rivatives of 1()Dr



were fitted to Gaussian functions.

1()



r exp









- 2



exp [

rc]

1()





'' 3

132

exp exp

Dr rr





 







 



1exp 2











= -1.176029 fm-1,



=5.118019 fm-4 2

(4.367436)1/2 fm-1 and 3

c= (2.117112)1/2 fm-1. The

spin-orbit part of COGEP is,



LS ij

COGEP



=- 4





λλ











()2()

ijij ij

rppDr Dr

















σσ

 

(14)

where

0()



 

exp exp

 



 



 



 





1ij



= 2 (1

rexp









- 2



exp









)

where 1



=2.680358 fm-1, 2



=-7.598860 fm-2 and 1

(2.373588)1/2.

It should be noted that in the limit c  0, the central,

tensor and spin-orbit part of the COGEP goes over to the

corresponding potentials of the OGEP [3].

The central part of III potential is given by [8-12,16],







,0 ,0

8,1,

8,1/2,

8,0

ij SL

III

ijS L

gr forI

rforI





 



























(15)

The symbols S, L and I are respectively the spin, the

relative angular momentum and the iso-spin of the sys-

tem. The

and



are the coupling constants of the

interaction. The Dirac delta-function appearing has been

regularized and replaced by a Gaussian- like function:



1exp ij

















(16)

where



is the size parameter.

The non-central part of III has contributions from both

spin- orbit and tensor terms. The spin-orbit contribution

comes from relativistic corrections to the central poten-

tial of III. It is given by [8-12],









SO ij ijij

III LSL

Vr VrLSVrL





 





(17)

The first term in Eq.17 is the traditional symmetric

spin-orbit term proportional to the operatorLS







. The

other term is the anti-symmetric spin-orbit term propor-

tional to L









where





 





. The radial

functions of Eq.17 are expressed as [8-12],



2ij

22 3

4ij 2

=3 -2

exp- r

exp-r

LS k

ij k

Vr MM

































(18)

and



6ij -4

ij 22 3

=5 -4

exp- r

ij k

Vr MM





















(19)

The term ()



is responsible for the spitting of the

L states with 1, L, L+1. JL



 With such a

term Lis still good quantum numbers but S is not. The

term





) which couples states 1

L and 3



Due to the mass dependence in Eq.19, it is clear that this

term is inoperative when the quarks are identical. In

practice the antisymmetric spin obit term is important

A. P. Monteiro et al. / Natural Science 2 (2010) 1292-1297

1295

only in the K-sector. The terms i and i are free pa-

rameters in the theory [12]. Mi corresponds to the mass

of the strange quark (s) and Mj corresponds to mass of

(u/d) quark. This term accounts for the splitting between

11D2 and 13D2 states in the K sector.

The tensor interaction of III is [12],







8ij -4

ij 3

=7 -4

ˆexp- r

TEN

III k

ij k

VrMM









 (20)

with the tensor interaction, L is no longer a good quan-

tum number since this term couples the states 3





and 3

(2)

L

.

The parameters of the RHM are the masses of the

quarks, Mu=Md and Ms, the respective confinement

strengths, Au

2=Ad

2, As

2, and the oscillator size parameter

bn (=1/ n

). They have been chosen to reproduce various

nucleon properties: the root mean square charge radius,

the magnetic moment and the ratio of the axial coupling

to the vector coupling [13]. The confinement strength

Au,d is fixed by the stability condition for the nucleon

mass against the variation of the size parameter bn

NH N



 (21)

The parameters associated with the strange quark Ms

and As

2 have been fitted in order to reproduce the mag-

netic moments of the strange baryons, according to the

procedure described in [16]. The



of COGEP is

fixed from S wave meson spectroscopy [16]. The value



turns out to be 0.2 for D wave mesons, which is

compatible with the perturbative treatment. Among the

non central parts of the potential, the hyperfine terms of

III has 12 additional strength and size parameters



’s

and



’s ( in Eqns. 18-20) respectively. We note that the



values can have both positive and negative values

[8-12]. The values of the III parameters



’s and



’s

are fixed from S and P wave meson spectroscopy [12,16]

and are listed in Table 1 and 2.

Table 1. The parameters for the D wave mesons.

b 0.62 fm

Mu,d 380 MeV

Ms 560 MeV



0.2



0.2 fm



0.29 fm



1.4 fm



1.3 fm



1.8



1.7



1.9



2.1



-22.0



-24.5

Table 2. Values of 7



and 8



parameters.

Meson 7



(1650)



28.0 36.0

K*(1680) 49.0 52.0

K2(1820) 36.0 45.0



(1670) -1.6 -6.5

K*(1780) 1.0 -2.5



(1850) -4.0 -8.0

3. RESULTS AND DISCUSSIONS

To calculate the meson masses, the product of

quark-antiquark oscillator wave functions is expressed in

terms of oscillator wave functions corresponding to the

relative and CM coordinates. The oscillator quantum

number for the CM wave functions is restricted to NCM =

0. The Hilbert space of relative wave functions is trun-

cated at radial quantum number nmax = 4. The Hamilto-

nian matrix is constructed for each meson separately in

the basis states of 21

0,0; S

CM CMJ

NL L



 and di-

agonalised.

We have obtained the D wave meson spectra using the

model described above. The masses of the singlet and

triplet D wave mesons after diagonalisation in harmonic

oscillator basis with nmax= 4 are listed in Tables 3 and 4

respectively. The results show that III potential along

with COGEP is necessary to obtain the meson mass

spectra. If COGEP is taken as the only source of hyper-

fine interaction, the value of αs necessary to reproduce

the hadrons spectrum is generally much larger than one;

this leads to a large spin-orbit interaction, which de-

stroys the overall fit to the spectrum. The inclusion of III

diminishes the relative importance of COGEP for the

hyperfine splitting. The important role played by III in

obtaining the masses of these mesons can be well under-

stood by examining the Table 6. In Table 6, we have

given the calculated masses of triplet D wave mesons

Table 3. Masses of the singlet mesons (in MeV ).

N2S+1LJ Meson Experimental

Mass

Calculated

Mass



(1670)1670±20 1673.8

11D2

K2 (1770) 1773±8 1768.8

Table 4. Masses of the triplet mesons ( in MeV ).

N2S+1LJMeson Experimental

Mass Calculated Mass

(1650)



1649 ± 24 1649.6

13D1 K*(1680)1717 ± 27 1718.9

13D2 K

2(1820)1816 ±13 1818.6



(1670)1667 ± 4 1667.8

K*(1780)1776 ± 7 1778.3

13D3



(1850) 1854 ± 7 1855.9

A. P. Monteiro et al. / Natural Science 2 (2010) 1292-1297

1296

Table 5. The diagonal contributions to the masses of mesons by Vconf, color-electric (CE), color-magnetic

(CM), spin-orbit, tensor terms of COGEP and spin-orbit, tensor terms of III (in MeV).

Meson Vconf CE

COGEP

V CM

COGEP

VLS

COGEP

V TEN

COGEP

V LS

III

V TEN

III



(1670) 1675.26 -2.83 1.43 ... ... ... ...

K2 (1770) 1770.79 -3.13 1.22 ... ... ... ...

(1650)



1675.26 -2.83 -0.48 2.12 0.44 -41.83 -257.09

K*(1680) 1770.79 -3.13 -0.41 1.81 -0.38 -29.74 -273.60

K2(1820) 1770.79 -3.13 -0.41 0.60 0.38 -9.91 220.59



(1670) 1675.26 -2.83 -0.48 -1.41 -0.13 27.89 9.59

K*(1780) 1770.79 -3.13 -0.41 -1.21 -0.11 19.83 1.34



(1850) 1866.32 -3.42 -0.35 -1.05 -0.09 12.84 6.43

Table 6. Masses of triplet mesons ( in MeV ) without III.

Meson Experimental Mass

Calculated Mass

without III

(1650)



1649 ± 24 1676.3

K*(1680) 1717 ± 27 1770.9

K2(1820) 1816 ±13 1768.2



(1670) 1667 ± 4 1670.4

K*(1780) 1776 ± 7 1765.9



(1850) 1854 ± 7 1861.4

without the inclusion of III potential. The role of III is

crucial in explaining the mass differences of D wave K

mesons. The Table 5 gives the diagonal contributions to

the masses of D wave mesons by the confinement poten-

tial, colour-electric (CE), colour-magnetic (CM), spin-

orbit, tensor terms of COGEP and spin-orbit, tensor

terms of III. In case of singlet D wave mesons, tensor

and spin-orbit terms of COGEP and III do not contribute

to the masses. In case of these singlet mesons the CE

part of COGEP is attractive, whereas the CM part of

COGEP is repulsive. The dominant contribution to the

calculated masses comes from the confinement potential.

In case of triplet D wave mesons the contribution of III

potential is very significant. From Table 5, we note that

the significant contribution to the masses of 13D1 mesons

arises from the tensor term of III which is attractive. The

tensor term involves the parameters k7 and k8. It was

necessary to tune k7 and k8 parameters to get a reasona-

bly good agreement with the experimental masses.

Hence in our model, we have only two free parameters

k7 and k8. For 13D1 mesons along with the tensor contri-

bution of III, the spin orbit contribution of III is also

significant and is attractive. The contribution of tensor

term of III in case of 13D2 is repulsive that significantly

increases the value of calculated mass. It is to be noted

that the anti-symmetric spin orbit potential of III con-

tributes substantially to the mass difference between the

11D2 and 13D2 mesons in the K meson sector. The mass

difference between K*(1680) and K2(1820) mesons is

due to the large difference in tensor part of III potential.

The tensor III potential is attractive for K*(1680) but is

repulsive for K2(1820) [17]. In case of 13D3 mesons the

contribution due to spin-orbit part of III potential is

dominant compared to that of tensor part which is repul-

sive. From Tables 3 and 4, it is clear that the calculated

meson masses are in good agreement with the experi-

mental masses [18].

4. CONCLUSIONS

We have investigated the effect of the III on the

masses of the D wave mesons in the frame work of

RHM. We have shown that the computation of the

masses using only COGEP is inadequate. The contribu-

tion of the III is found to be significant. To obtain the

masses of D wave mesons, 5x5 Hamiltonian matrix was

diagonalised. The contribution from the tensor and

spin-orbit part of the III is found to be significant in case

of triplet D wave mesons. To obtain the physical masses

of the mesons in the K sector it is necessary to include

the anti-symmetric part of III. There is a good agreement

between the calculated and experimental masses of D

wave mesons. To enhance the performance of the model,

there is a need to make a global chi-square fit of the pa-

rameters and also to test different wave functions which

would ultimately give better result. Also, the model has

to be tested to calculate the leptonic and radiative decay

widths. Work in this direction is in progress.

5. ACKNOWLEDGEMENTS

One of the authors (APM) is grateful to the DST, India, for granting

the JRF. The other author (KBV) acknowledges the DST for funding

the project (Sanction No. SR/S2/HEP-14/2006) and the fruitful discus-

sion he had with Y.L. Ma of IHEP, Beijing.

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