On the Tensor Glueball Content of Soft Pomeron

ZHOU Li-Juan; MA Wei-Xing

Chinese Physics C> 2003, Vol. 27> Issue(10) : 857-865

On the Tensor Glueball Content of Soft Pomeron

ZHOU Li-Juan ,
MA Wei-Xing ^, ,

Department of Information and Computing Science,Guang xi University of Technology,Liuzhou 545006,China2 Institute of High Energy Physics,CAS,Beijing 100039,China3 T-16,Theoretical Division,Los Alamos National Laboratory,Los Alamos,NM 87545,USA

Abstract
HTML
Reference
Related

PDF

Abstract：
We study the gluonic content of the pomeron through relating the pomeron trajectory to the observed I^GJ^PC=0⁺2⁺⁺ isoscalar tensor mesons. Four of these mesons satisfy the spin-mass relation of the pomeron. These pomeronian candidates may be hybrid states. One of them, the f₂(2220) meson, can have a predominant glueball component. We address the unsettled experimental situation about the width of this meson and give a theoretical lower bound for it. We also show why this meson may not be seen in pp experiments.

References

[1]

Regge T. Nuovo Cimento, 1959, 14:951–960; 18:947–9612 Collins P D B. An Introduction to Regge Theory and High Energy Physics, Cambridge, Cambridge University Press, 1977． 1–99 3 Okum L B, Pomeranchuk I Y. Sov. Phys., 1956, 3:306–314; Okum L B, Pomeranchuk I Y. Sov. Phys., 1967, JETP3:307–3404 Groom D E, Aguilar–Benitez M, Amsler et al. Review of Particle Physics, Euro. Phys., 2000, J15:233–2355 Forshaw J R, Ross D A. Quantum Chromodynamics and The Pomerom, Cambridge, Cambridge University Press, 1977, 12–966 Jaroszkiewicz G A, Landshoff P V. Phys. Rev., 1974, D10:170–182; Donnachie A, Landshoff P V. Phys. Lett., 1983, B123:345–3627 The uncertainties were not given in the original articles and the results of refitting the same inputs by us.8 Block M A, Kang K, White A R. Int'l J. Mod. Phys., 1992, A7: 4449–44599 More precisely, the relation is σtot2(s)/σel(s)=16π(b + 2α' In(s))/(1+ρ2) with ρ being the ratio of the real to imaginary parts of the forward amplitude. However, in the energy region of interest, (ρ2 + 1) ≈ 110 Engene J, Kooijman P. Prog. Part. Nucl. Phys., 1998, 41:1–2011 Laget J M, Galain R M Nucl. Phys., 1995, A581:397–40612 Landshoff P V, Nachtmann O. Z. Phys., 1987, C35:405–416 13 Low F E. Phys, Rev., 1975, D12:163–17614 Nussinov S. Phys. Rev. lett., 1975, 34:163–17615 Fadin V, Kuraev E A, Lipatov L N. Sov. Phys. 1977, JETP45: 199–224; Balitxky Y Y, Lipatov L N. Sov. J. nucl. Phys., 1978, 28 : 822–834 16 Dokshitzer Y L. Sov. Phys. 1977, JETP73: 1216–1229; Gribov V N, Lipatov L N. Soc. J. Nucl., 1978, 15:72–81; Altarelli G Parisi G. Nuel. Phys., 1977, B126:298–312 17 Collin J M, Peardon M. Phys. Rev., 1999, i)60:034509––034560 18 Adam S, Swanson E S, Ji C R, Stephen R C. Phys. Rev. Lett., 1996, 76:2011–202619 Kisslinger L S, MA Wei–Xing. Phys. Lett., 2000, B485:367–37120 Close F E, Glennys F R, Li Z P. Phys. Rev., 1997, D55:5749–576021 Levin E. 25 years with the Pomeron, Aug. 1998, DESY 98–118, TAUP2521/98, hep–ph/9808483, 31 Aug. 199822 Michael C. AIP Conference Proc. , 1997, 432:657–68223 Burakovsky L. Phys. Rev., 1998, D58:057503–057521 24 Close F E. Preprint, hep–hp/9701290 at ⅩⅩⅩ. lanl.gov 25 Burakovsky L. Page P R. Euro. Phys. J., 2000, C12:480–49626 Baltkusaitis R M. Phys. Rev. Lett., 1986, 56:107–114 27 Alde D M. Phys. Lett., 1986, B177:120–12628 Aston D. Phys. Lett., 1988, B215:199–20429 Breitweg J. DESY 98–107; Abatzis S. Phys. Lett., 1994, B324: 509–51430 BAI J Z. Phys. Rev. Lett., 1996, 76:3502–351031 Seth K K. Nucl. Phys., 2000, A675:25–35c32 Predazzi E. Diffraction: Past, Present and Future. 1999, Preprint, INFEN, Sezione di Torino, 10125 Torino, Italy 33 LIU L C, MAW X. J. Phys., 2000, G26:L59–64 34 BAI J Z. Phys. Rev. Lett., 1998, 81:1179–118435 SHEN X. in Hadron Spectroscopy, ed. By Chung S U, Willutzki H, AIP Conf. Proc. 1998, 432:47–60 36 Jacob M, Wick G C. Ann. Phys. (N. Y.), 1959, 7:404–45637 Haider Q, LIU L C. J. Phys., 1996, G22:1187–1198 38 Martin A D, Spearman T D. Elementary Particle Theory, North–Holland Publ. Co.–Amsterdam and John Wiley Sons, Inc.–New York, 1970, 46–89

[1]	ZHU Wei , SHEN Zhen-Qi . Properties of the gluon Recombination Functions. Chinese Physics C, 2005, 29(2): 109-114.
[2]	ZHOU Li-Juan , HE Xiao-Rong , MA Wei-Xing . Pomeron-Nucleon Coupling in QCD. Chinese Physics C, 2005, 29(9): 856-861.
[3]	PENG Hong-An , XING Xiu-Wen , LIU Lian-Shou . On the Structure of Soft Pomeron. Chinese Physics C, 2005, 29(3): 224-231.
[4]	ZHANG Zhu-Feng , JIN Hong-Ying . Effect of Instanton on the QCD Sum Rule of 0⁺⁺ Glueball. Chinese Physics C, 2004, 28(3): 245-249.
[5]	ZHU Ying-Chun , SHEN Xiao-Yan , ZHENG Zhi-Peng . Monte Carlo Simulation of Searching for Glueball on BEPCⅡ/BESⅢ. Chinese Physics C, 2003, 27(7): 559-563.
[6]	LI Lin , WU Xiang-Yao , HUANG Tao . B→KK Decays with the Soft-Gluon Corrections. Chinese Physics C, 2003, 27(8): 678-682.
[7]	MA Wei-Xing , ZHOU Li-Juan , . Does the Tensor Glueball ξ(2230) Exist?. Chinese Physics C, 2002, 26(4): 309-312.
[8]	LI DeMin , FANG Jian , YU Hong , SHEN QiXing . Mixing of the Neutral Tensor Mesons f₂(1270),f′₂(1525) and the Glueball Candidate ξ(2230). Chinese Physics C, 2000, 24(5): 451-456.
[9]	Ma Weixing , Liu Longchang , Shen Pengnian . Gluonic Content of the Pomeron. Chinese Physics C, 1999, 23(12): 1253-1256.
[10]	He Zejun . Characteristic Dilepton Distribution for Quark-Gluon Matter. Chinese Physics C, 1997, 21(3): 269-274.
[11]	Lu Wentao , liu Jueping . QCD Sum Rules for the 0⁺⁺ Three-Gluon Scalar Glueball. Chinese Physics C, 1996, 20(8): 691-697.
[12]	Cao Zhen , Ding Linkai . Chou-Yang Model for the Description of Ultrahigh Energy Soft Hadronic Interactions. Chinese Physics C, 1994, 18(11): 990-995.
[13]	TIAN Li-Li , XIE Qu-Bing . Gluon Fragmentation in Υ Decay. Chinese Physics C, 1993, 17(10): 885-891.
[14]	SHEN Qi-Xing , YU Hong . The Polarization States of the Gluon and the Glueball Interpretation of the ξ(2230). Chinese Physics C, 1991, 15(5): 477-480.
[15]	YU Hong . A DIRECT CHECK FOR G(1590) AS THE 0⁺⁺ GLUEBALL CANDIDATE. Chinese Physics C, 1990, 14(3): 286-288.
[16]	SHEN Qi-Xing , YU Hong . GLUEBALL EXPLANATION FOR THE ξ(2230). Chinese Physics C, 1990, 14(5): 477-480.
[17]	YU Hong , SHEN Qi-Xing , WANG Xu . d WAVE COMPONENTS OF THE GLUEBALL CANDIDATE θ/f₂(1720) AND POSSIBLE EXPERIMENTAL TEST. Chinese Physics C, 1989, 13(11): 996-1002.
[18]	XIE Qu-Bing . THE COLLIDING COMPONENT IN SOFT HADRONIC INTERACTIONS. Chinese Physics C, 1984, 8(3): 306-315.
[19]	YU Hong , LI Bing-An , SHEN Qi-Xing , ZHANG Mei-Man . GLUEBALL COMPONENT OF THE PSEUDOMESON AND ITS PRODUCTION IN J/ψ RADIATIVE DECAY. Chinese Physics C, 1984, 8(3): 285-290.
[20]	SHEN Qi-Xing , LI Bing-An , YU Hong , ZHANG Mei-Man . PRODUCTION OF A 3^－+ GLUEBALL IN J/ψ RADIATIVE DECAY. Chinese Physics C, 1984, 8(5): 573-578.

Access

Get Citation

ZHOU Li-Juan, MA Wei-Xing and On the Tensor Glueball Content of Soft Pomeron[J]. Chinese Physics C, 2003, 27(10): 857-865.

ZHOU Li-Juan, MA Wei-Xing and On the Tensor Glueball Content of Soft Pomeron[J]. Chinese Physics C, 2003, 27(10): 857-865. shu

RIS(for EndNote,Reference Manager,ProCite)

BibTex

Txt

Milestone

Received: 2003-03-10
Revised: 1900-01-01

Article Metric

Article Views(2746)
PDF Downloads(496)
Cited by(0)

Policy on re-use

To reuse of subscription content published by CPC, the users need to request permission from CPC, unless the content was published under an Open Access license which automatically permits that type of reuse.

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

On the Tensor Glueball Content of Soft Pomeron

Corresponding author: MA Wei-Xing,

Department of Information and Computing Science,Guang xi University of Technology,Liuzhou 545006,China2 Institute of High Energy Physics,CAS,Beijing 100039,China3 T-16,Theoretical Division,Los Alamos National Laboratory,Los Alamos,NM 87545,USA

Received Date: 2003-03-10

Accepted Date: 1900-01-01

Available Online: 2003-10-05

Abstract: We study the gluonic content of the pomeron through relating the pomeron trajectory to the observed I^GJ^PC=0⁺2⁺⁺ isoscalar tensor mesons. Four of these mesons satisfy the spin-mass relation of the pomeron. These pomeronian candidates may be hybrid states. One of them, the f₂(2220) meson, can have a predominant glueball component. We address the unsettled experimental situation about the width of this meson and give a theoretical lower bound for it. We also show why this meson may not be seen in pp experiments.

HTML

Reference (1)

On the Tensor Glueball Content of Soft Pomeron

Abstract：

References

Access

Article Metrics

Metrics

通讯作者: 陈斌, bchen63@163.com

Email This Article