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Measurement of the e+e−→π+π− cross section between 600 and 900 MeV using initial state radiation

Authors :
M. Ablikim
M.N. Achasov
X.C. Ai
O. Albayrak
M. Albrecht
D.J. Ambrose
A. Amoroso
F.F. An
Q. An
J.Z. Bai
R. Baldini Ferroli
Y. Ban
D.W. Bennett
J.V. Bennett
M. Bertani
D. Bettoni
J.M. Bian
F. Bianchi
E. Boger
I. Boyko
R.A. Briere
H. Cai
X. Cai
O. Cakir
A. Calcaterra
G.F. Cao
S.A. Cetin
J.F. Chang
G. Chelkov
G. Chen
H.S. Chen
H.Y. Chen
J.C. Chen
M.L. Chen
S.J. Chen
X. Chen
X.R. Chen
Y.B. Chen
H.P. Cheng
X.K. Chu
G. Cibinetto
H.L. Dai
J.P. Dai
A. Dbeyssi
D. Dedovich
Z.Y. Deng
A. Denig
I. Denysenko
M. Destefanis
F. De Mori
Y. Ding
C. Dong
J. Dong
L.Y. Dong
M.Y. Dong
S.X. Du
P.F. Duan
E.E. Eren
J.Z. Fan
J. Fang
S.S. Fang
X. Fang
Y. Fang
L. Fava
F. Feldbauer
G. Felici
C.Q. Feng
E. Fioravanti
M. Fritsch
C.D. Fu
Q. Gao
X.Y. Gao
Y. Gao
Z. Gao
I. Garzia
K. Goetzen
W.X. Gong
W. Gradl
M. Greco
M.H. Gu
Y.T. Gu
Y.H. Guan
A.Q. Guo
L.B. Guo
Y. Guo
Y.P. Guo
Z. Haddadi
A. Hafner
S. Han
X.Q. Hao
F.A. Harris
K.L. He
X.Q. He
T. Held
Y.K. Heng
Z.L. Hou
C. Hu
H.M. Hu
J.F. Hu
T. Hu
Y. Hu
G.M. Huang
G.S. Huang
J.S. Huang
X.T. Huang
Y. Huang
T. Hussain
Q. Ji
Q.P. Ji
X.B. Ji
X.L. Ji
L.W. Jiang
X.S. Jiang
X.Y. Jiang
J.B. Jiao
Z. Jiao
D.P. Jin
S. Jin
T. Johansson
A. Julin
N. Kalantar-Nayestanaki
X.L. Kang
X.S. Kang
M. Kavatsyuk
B.C. Ke
P. Kiese
R. Kliemt
B. Kloss
O.B. Kolcu
B. Kopf
M. Kornicer
W. Kühn
A. Kupsc
J.S. Lange
M. Lara
P. Larin
C. Leng
C. Li
Cheng Li
D.M. Li
F. Li
F.Y. Li
G. Li
H.B. Li
J.C. Li
Jin Li
K. Li
Lei Li
P.R. Li
T. Li
W.D. Li
W.G. Li
X.L. Li
X.M. Li
X.N. Li
X.Q. Li
Z.B. Li
H. Liang
Y.F. Liang
Y.T. Liang
G.R. Liao
D.X. Lin
B.J. Liu
C.X. Liu
F.H. Liu
Fang Liu
Feng Liu
H.B. Liu
H.H. Liu
H.M. Liu
J. Liu
J.B. Liu
J.P. Liu
J.Y. Liu
K. Liu
K.Y. Liu
L.D. Liu
P.L. Liu
Q. Liu
S.B. Liu
X. Liu
Y.B. Liu
Z.A. Liu
Zhiqing Liu
H. Loehner
X.C. Lou
H.J. Lu
J.G. Lu
Y. Lu
Y.P. Lu
C.L. Luo
M.X. Luo
T. Luo
X.L. Luo
X.R. Lyu
F.C. Ma
H.L. Ma
L.L. Ma
Q.M. Ma
T. Ma
X.N. Ma
X.Y. Ma
F.E. Maas
M. Maggiora
Y.J. Mao
Z.P. Mao
S. Marcello
J.G. Messchendorp
J. Min
R.E. Mitchell
X.H. Mo
Y.J. Mo
C. Morales Morales
K. Moriya
N.Yu. Muchnoi
H. Muramatsu
Y. Nefedov
F. Nerling
I.B. Nikolaev
Z. Ning
S. Nisar
S.L. Niu
X.Y. Niu
S.L. Olsen
Q. Ouyang
S. Pacetti
P. Patteri
M. Pelizaeus
H.P. Peng
K. Peters
J. Pettersson
J.L. Ping
R.G. Ping
R. Poling
V. Prasad
M. Qi
S. Qian
C.F. Qiao
L.Q. Qin
N. Qin
X.S. Qin
Z.H. Qin
J.F. Qiu
K.H. Rashid
C.F. Redmer
M. Ripka
G. Rong
Ch. Rosner
X.D. Ruan
V. Santoro
A. Sarantsev
M. Savrié
K. Schoenning
S. Schumann
W. Shan
M. Shao
C.P. Shen
P.X. Shen
X.Y. Shen
H.Y. Sheng
W.M. Song
M.R. Shepherd
X.Y. Song
S. Sosio
S. Spataro
G.X. Sun
J.F. Sun
S.S. Sun
Y.J. Sun
Y.Z. Sun
Z.J. Sun
Z.T. Sun
C.J. Tang
X. Tang
I. Tapan
E.H. Thorndike
M. Tiemens
M. Ullrich
I. Uman
G.S. Varner
B. Wang
D. Wang
D.Y. Wang
K. Wang
L.L. Wang
L.S. Wang
M. Wang
P. Wang
P.L. Wang
S.G. Wang
W. Wang
X.F. Wang
Y.D. Wang
Y.F. Wang
Y.Q. Wang
Z. Wang
Z.G. Wang
Z.H. Wang
Z.Y. Wang
T. Weber
D.H. Wei
J.B. Wei
P. Weidenkaff
S.P. Wen
U. Wiedner
M. Wolke
L.H. Wu
Z. Wu
L.G. Xia
Y. Xia
D. Xiao
H. Xiao
Z.J. Xiao
Y.G. Xie
Q.L. Xiu
G.F. Xu
L. Xu
Q.J. Xu
X.P. Xu
L. Yan
W.B. Yan
W.C. Yan
Y.H. Yan
H.J. Yang
H.X. Yang
L. Yang
Y. Yang
Y.X. Yang
M. Ye
M.H. Ye
J.H. Yin
B.X. Yu
C.X. Yu
J.S. Yu
C.Z. Yuan
W.L. Yuan
Y. Yuan
A. Yuncu
A.A. Zafar
A. Zallo
Y. Zeng
B.X. Zhang
B.Y. Zhang
C. Zhang
C.C. Zhang
D.H. Zhang
H.H. Zhang
H.Y. Zhang
J.J. Zhang
J.L. Zhang
J.Q. Zhang
J.W. Zhang
J.Y. Zhang
J.Z. Zhang
K. Zhang
L. Zhang
X.Y. Zhang
Y. Zhang
Y.N. Zhang
Y.H. Zhang
Y.T. Zhang
Yu Zhang
Z.H. Zhang
Z.P. Zhang
Z.Y. Zhang
G. Zhao
J.W. Zhao
J.Y. Zhao
J.Z. Zhao
Lei Zhao
Ling Zhao
M.G. Zhao
Q. Zhao
Q.W. Zhao
S.J. Zhao
T.C. Zhao
Y.B. Zhao
Z.G. Zhao
A. Zhemchugov
B. Zheng
J.P. Zheng
W.J. Zheng
Y.H. Zheng
B. Zhong
L. Zhou
X. Zhou
X.K. Zhou
X.R. Zhou
X.Y. Zhou
K. Zhu
K.J. Zhu
S. Zhu
S.H. Zhu
X.L. Zhu
Y.C. Zhu
Y.S. Zhu
Z.A. Zhu
J. Zhuang
L. Zotti
B.S. Zou
J.H. Zou
Source :
Physics Letters B, Vol 753, Iss C, Pp 629-638 (2016)
Publication Year :
2016
Publisher :
Elsevier, 2016.

Abstract

We extract the e+e−→π+π− cross section in the energy range between 600 and 900 MeV, exploiting the method of initial state radiation. A data set with an integrated luminosity of 2.93 fb−1 taken at a center-of-mass energy of 3.773 GeV with the BESIII detector at the BEPCII collider is used. The cross section is measured with a systematic uncertainty of 0.9%. We extract the pion form factor |Fπ|2 as well as the contribution of the measured cross section to the leading-order hadronic vacuum polarization contribution to (g−2)μ. We find this value to be aμππ,LO(600–900MeV)=(368.2±2.5stat±3.3sys)⋅10−10, which is between the corresponding values using the BaBar or KLOE data.

Subjects

Subjects :
Hadronic cross section
Muon anomaly
Initial state radiation
Pion form factor
BESIII
Physics
QC1-999

Details

Language :
English
ISSN :
03702693 and 18732445
Volume :
753
Issue :
C
Database :
Directory of Open Access Journals
Journal :
Physics Letters B
Publication Type :
Academic Journal
Accession number :
edsdoj.f18fcb4941614760805c259e02ce522e
Document Type :
article
Full Text :
https://doi.org/10.1016/j.physletb.2015.11.043
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