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Ablikim, M.; Bai, J. Z.; Ban, Y.; Bian, J. G.; Cai, Xinxia; Chen, H. F.; Chen, H. S.; Chen, H. X.; Chen, J. C.; Chen, Jin; Chen, Y. B.; P., S.; Chu, Y. P.; Cui, X. Z.; Dai, Y. S.; Diao, L. Y.; Deng, Z. Y.; Dong, Qingshun; Du, S. X.; Fang, J.; Fang, S. S.; Fu, C. D.; Gao, C. S.; Gao, Yang; Gu, S.; Gu, Y. T.; Guo, Y. N.; Guo, Y. Q.; Guo, Z. J.; Harris, F. A.; He, K. L.; He, M.; Heng, Y. K.; Hu, H. M.; Hu, T.; Huang, G. S.; Huang, X.; Ji, X. B.; Jiang, X. S.; Jiang, X. Y.; Jiao, J. B.; Jin, D. P.; Jin, S.; Jin, Y.; Lai, Y. F.; Li, G.; Li, H. B.; Li, H. H.; Li, J.; Li, R. Y.; Li, S. M.; Li, W. D.; Li, W. G.; Li, X. L.; Li, X. N.; Li, X. Q.; Li*, Yuetai; Liang, Y. F.; Liao, H.; Liu, B. J.; Liu, C. X.; Liu, F.; Liu, Fang; Liu, H. H.; Liu, Hao; Liu, J.; Liu, J. B.; Liu, J. P.; Q., Liu,; Liu, R. G.; Liu, Z. A.; Lou, Yunjiang; Lu, F. X.; Lu, G. R.; Lü, J. G.; Luo, C. L.; C., F.; L., H.; L., L.; M., Q.; B., X.; Mao, Z. P.; Mo, X. H.; Nie, J.; Olsen, S. L.; Peng, H.; Ping, R. G.; Qi, N. D.; H, Qin; Qiu, J. F.; Ren, Z.; Rong, G.; Shan, L. Y.; Shang, L.; Shen, C. P.; Shen, D. L.; Shen, X. Y.; Sheng, H. Y.; Sun, H.; Sun, J. F.; Sun, S. S.; Sun, Y. Z.; Sun, Z. J.; Tan, Zhengguo; Tang, X.; Tong, G. L.; Varner, G.; Wang, D. Y.; Wang, L.; Wang, L. L.; Wang, L. S.; Wang, M.; Wang, P.; Wang, P. L.; Wang, W. F.; Wang, Yiwen; Wang, Z.; Wang, Z. Y.; Wang, Zhe; Wang, Zheng; Chen, Wei; Wei, D. H.; Wu, N.; Xia, X. M.; Xie, X. X.; Xu, G. F.; Xu, X. P.; Xu, Y. C.; Yan, Mu-Lin; Yang, H. X.; Yang, Yifan; Ye, M. H.; Ye, Y. X.; Yi, Z. Y.; Yu, G.; Yuan, C. Z.; Yuan, J. M.; Yuan, Y.; Zang, S. L.; Zeng, Y.; Zhang, B. X.; Zhang, B. Y.; Zhang, C. C.; Zhang, D. H.; Zhang, H. Q.; Zhang, H. Y.; Zhang, J. W.; Zhang, J. Y.; Zhang, Shengyu; Zhang, Xinyu; Zhang, X. Y.; Zhang, Yiyun; Zhang, Z. P.; Zhao, Dongxu; Zhao, J. W.; Zhao, M. G.; Zhao, P. P.; Zhao, W. R.; Zhao, Z.; Zheng, Hanqing; Zheng, J. P.; Zheng, Z. P.; Li, Zhou; Zhou, Na; Zhu, K. J.; Zhu, Q. M.; Zhu, Y.; Zhu, Y. S.; Zhu, Y. S.; Zhu, Z. A.; Zhuang, B. A.; Zhuang, X.; Zou, B. S.

doi:10.1103/physrevlett.97.202002

Cited by 55 publications

(56 citation statements)

References 20 publications

Supporting

Mentioning

Contrasting

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“…[15], which in our case are M ψ , g ψe + e − , A and R. M ψ is of course very close to the nominal mass of the ψ(3770), g ψe + e − determines the strength of the cross section, A is related to the width of the resonance, and R determines the fall down of the resonance shape above the resonance peak. The parameters are fitted to the data of the cross section for e + e − → DD [12][13][14].…”

Section: Resultsmentioning

confidence: 99%

“…[11] were based on a particular quark model. , [13], [14]) for the cross section of e + e − → D 0D0 reaction, using the form factor of Eq. (34) and the parameters in Table II.…”

Section: Resultsmentioning

confidence: 99%

“…This is a reasonable number, but in view of the results in Table V with the former fit, we can settle the value of Z within 0.80 ∼ 0.85, which is a reasonable range of uncertainty. , [13], [14]) using the form factor of Eq. (33).…”

Section: A Evaluation Of the Vector And Meson-meson Probabilitiesmentioning

confidence: 99%

“…The asymmetry of the ψ(3770) peak observed in the e + e − → DD reactions [12][13][14] has been the subject of the intense discussion (see Ref. [15] for a recent review).…”

Section: Introductionmentioning

confidence: 99%

“…Cross section of e + e − → D + D − fitted to the experimental data (•[12],[13],[14]) using the form factor of Eq. (34).…”

mentioning

confidence: 99%

See 4 more Smart Citations

Line shape and D()D¯(
Yu
¹
,
Wu
²
,
Bayar
³

et al. 2019
Phys. Rev. D
8
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0
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We have performed a calculation of the DD, DD * , D * D , D * D * components in the wave function of the ψ(3770). For this we make use of the 3 P 0 model to find the coupling of ψ(3770) to these components, that with an elaborate angular momentum algebra can be obtained with only one parameter. Then we use data for the e + e − → DD reaction, from where we determine a form factor needed in the theoretical frame work, as well as other parameters needed to evaluate the meson-meson selfenergy of the ψ(3770). Once this is done we determine the Z probability to still have a vector core and the probability to have the different meson components. We find Z about 80 ∼ 85%, and the individual meson-meson components are rather small, providing new empirical information to support the largely qq component of vector mesons, and the ψ(3770) in particular.

show abstract

Section: Resultsmentioning

confidence: 99%

“…[11] were based on a particular quark model. , [13], [14]) for the cross section of e + e − → D 0D0 reaction, using the form factor of Eq. (34) and the parameters in Table II.…”

Section: Resultsmentioning

confidence: 99%

Section: A Evaluation Of the Vector And Meson-meson Probabilitiesmentioning

confidence: 99%

“…The asymmetry of the ψ(3770) peak observed in the e + e − → DD reactions [12][13][14] has been the subject of the intense discussion (see Ref. [15] for a recent review).…”

Section: Introductionmentioning

confidence: 99%

“…Cross section of e + e − → D + D − fitted to the experimental data (•[12],[13],[14]) using the form factor of Eq. (34).…”

mentioning

confidence: 99%

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Line shape and D()D¯(
Yu
¹
,
Wu
²
,
Bayar
³

et al. 2019
Phys. Rev. D
8
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40
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show abstract

Chiral constituent quark model study of the process γp → ηp

He¹,

Saghai²,

Li³

et al. 2008

Nstar 2007

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Within a chiral constituent quark model approach, η-meson production on the proton via electromagnetic and hadron probes are studied. With few parameters, differential crosssection and polarized beam asymmetry for γp → ηp and differential cross section for π − p → ηn processes are calculated and successfully compared with the data in the centerof-mass energy range from threshold up to 2 GeV. The five known resonances S 11 (1535), S 11 (1650), P 13 (1720), D 13 (1520), and F 15 (1680) are found to be dominant in the reaction mechanisms in both channels. Possible roles plaied by new resonances are also investigated and in the photoproduction channel, significant contribution from S 11 -and D 15 -resonances, with masses around 1715 MeV and 2090 MeV, respectively, are deduced. For the so-called missing resonances, no evidence is found within the investigated reactions. The helicity amplitudes and decay widths of N * → πN, ηN are also presented, and found consistent with the PDG values.both differential cross section [2, 3,4,5], and polarized beam asymmetry [5,6]. The situation is very different for the π − p → ηn reaction. Actually, the data come mainly from measurements performed in 70's [7,8,9,10,11,12] and suffer from some inconsistencies [13]. A recent experiment, performed at BNL using the Crystal Ball spectrometer [14], offers a high quality data set, though limited to the close to threshold kinematics. Consequently, a combined data base embodying experimental results for both electromagnetic and strong channels turns out to be highly heterogeneous. In spite of that uncomfortable situation, recent intensive theoretical investigations interpreting both channels within a single approach has proven to be fruitful in revealing various aspects of the relevant reaction mechanisms, as discussed, e.g., in Refs. [1,15].In the photoproduction sector, a significant progress has been performed in recent years within coupled-channels formalisms [16,17,18,19] allowing to investigate a large number of intermediate and/or final meson-baryon (MB) states: γN → M B, with M B ≡ πN, ηN, ρN, σN, π∆, KΛ, KΣ.Those approaches have been reviewed in our recent paper [1]. Also advanced coupled-channels approaches are being developed [15,20,21,22] for the strong channels: πN → M B. However, fewer studies embody both electromagnetic and strong production processes. Moreover, those works are based on the effective Lagrangian approaches (ELA), where meson-baryon degrees of freedom are implemented, (see e.g. Refs. [17,18,23,24]). Investigations based on subnucleonic degrees of freedom, via constituent quark models (CQM) have been successful [1,25,26,27,28,29] in the interpretation of photoproduction data on the proton, namely, γp → πN, ηp, KΛ, and a recent work [30] has considered the π − p → ηn reaction.At the present stage, the ELA and the CQM approaches are complementary. However, the QCDinspired CQM developments deal on the one hand with more fundamental degrees of freedom and on the other hand require a much smaller number of adjustable p...

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U(1)A symmetry in two-doublet models, U bosons or light scalars, and ψ and ϒ decays

Fayet

2009

Physics Letters B

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Search for Invisible Decays ofηandη′inJ/ψ→ϕηand
M. Ablikim¹,
J. Z. Bai²,
Y. Ban³
et al.

Cited by 55 publications

References 20 publications

Line shape and D()D¯(
Yu
¹
,
Wu
²
,
Bayar
³

et al. 2019
Phys. Rev. D
8
1
40
0
View full text Add to dashboard Cite

Line shape and D()D¯(
Yu
¹
,
Wu
²
,
Bayar
³

et al. 2019
Phys. Rev. D
8
1
40
0
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Chiral constituent quark model study of the process γp → ηp

U(1)A symmetry in two-doublet models, U bosons or light scalars, and ψ and ϒ decays

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Search for Invisible Decays ofηandη′inJ/ψ→ϕηandM. Ablikim1, J. Z. Bai2, Y. Ban3 et al.

Cited by 55 publications

References 20 publications

Line shape and D(*)D¯(*Yu1, Wu2, Bayar3 et al. 2019Phys. Rev. D81400View full textAdd to dashboardCite

Line shape and D(*)D¯(*Yu1, Wu2, Bayar3 et al. 2019Phys. Rev. D81400View full textAdd to dashboardCite

Chiral constituent quark model study of the process γp → ηp

U(1)A symmetry in two-doublet models, U bosons or light scalars, and ψ and ϒ decays

Contact Info

Product

Resources

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Search for Invisible Decays ofηandη′inJ/ψ→ϕηand
M. Ablikim¹,
J. Z. Bai²,
Y. Ban³
et al.

Line shape and D()D¯(
Yu
¹
,
Wu
²
,
Bayar
³

et al. 2019
Phys. Rev. D
8
1
40
0
View full text Add to dashboard Cite

Line shape and D()D¯(
Yu
¹
,
Wu
²
,
Bayar
³

et al. 2019
Phys. Rev. D
8
1
40
0
View full text Add to dashboard Cite