Deep view of Composite SNR CTA1 with LHAASO in $\gamma$-rays up to 300 TeV

Zhen Cao; F. Aharonian; Y.X. Bai; Y.W. Bao; D. Bastieri; X.J. Bi; Y.J. Bi; W. Bian; J. Blunier; A.V. Bukevich; C.M. Cai; Y.Y. Cai; W.Y. Cao; Zhe Cao; J. Chang; J.F. Chang; E.S. Chen; G.H. Chen; H.K. Chen; L.F. Chen; Liang Chen; Long Chen; M.J. Chen; M.L. Chen; Q.H. Chen; S. Chen; S.H. Chen; S.Z. Chen; T.L. Chen; X.B. Chen; X.J. Chen; X.P. Chen; Y. Chen; N. Cheng; Q.Y. Cheng; Y.D. Cheng; M.Y. Cui; S.W. Cui; X.H. Cui; Y.D. Cui; B.Z. Dai; H.L. Dai; Z.G. Dai; Danzengluobu; Y.X. Diao; A.J. Dong; X.Q. Dong; K.K. Duan; J.H. Fan; Y.Z. Fan; J. Fang; J.H. Fang; K. Fang; C.F. Feng; H. Feng; L. Feng; S.H. Feng; X.T. Feng; Y. Feng; Y.L. Feng; S. Gabici; B. Gao; Q. Gao; W. Gao; W.K. Gao; M.M. Ge; T.T. Ge; L.S. Geng; G. Giacinti; G.H. Gong; Q.B. Gou; M.H. Gu; F.L. Guo; J. Guo; K.J. Guo; X.L. Guo; Y.Q. Guo; Y.Y. Guo; R.P. Han; O.A. Hannuksela; M. Hasan; H.H. He; H.N. He; J.Y. He; X.Y. He; Y. He; S. Hern\'andez-Cadena; B.W. Hou; C. Hou; X. Hou; H.B. Hu; S.C. Hu; C. Huang; D.H. Huang; J.J. Huang; X.L. Huang; X.T. Huang; X.Y. Huang; Y. Huang; Y.Y. Huang; A. Inventar; X.L. Ji; H.Y. Jia; K. Jia; H.B. Jiang; K. Jiang; X.W. Jiang; Z.J. Jiang; M. Jin; S. Kaci; M.M. Kang; I. Karpikov; D. Khangulyan; D. Kuleshov; K. Kurinov; Cheng Li; Cong Li; D. Li; F. Li; H.B. Li; H.C. Li; Jian Li; Jie Li; K. Li; L. Li; R.L. Li; S.D. Li; T.Y. Li; W.L. Li; X.R. Li; Xin Li; Y. Li; Zhe Li; Zhuo Li; E.W. Liang; Y.F. Liang; S.J. Lin; B. Liu; C. Liu; D. Liu; D.B. Liu; H. Liu; J. Liu; J.L. Liu; J.R. Liu; M.Y. Liu; R.Y. Liu; S.M. Liu; W. Liu; X. Liu; Y. Liu; Y. Liu; Y.N. Liu; Y.Q. Lou; Q. Luo; Y. Luo; H.K. Lv; B.Q. Ma; L.L. Ma; X.H. Ma; I.O. Maliy; J.R. Mao; Z. Min; W. Mitthumsiri; Y. Mizuno; G.B. Mou; A. Neronov; K.C.Y. Ng; M.Y. Ni; L. Nie; L.J. Ou; Z.W. Ou; P. Pattarakijwanich; Z.Y. Pei; D.Y. Peng; J.C. Qi; M.Y. Qi; J.J. Qin; D. Qu; A. Raza; C.Y. Ren; D. Ruffolo; A. S\'aiz; D. Savchenko; D. Semikoz; L. Shao; O. Shchegolev; Y.Z. Shen; X.D. Sheng; Z.D. Shi; F.W. Shu; H.C. Song; Yu.V. Stenkin; V. Stepanov; Y. Su; D.X. Sun; H. Sun; J.X. Sun; Q.N. Sun; X.N. Sun; Z.B. Sun; N.H. Tabasam; J. Takata; P.H.T. Tam; H.B. Tan; Q.W. Tang; R. Tang; Z.B. Tang; W.W. Tian; C.N. Tong; L.H. Wan; C. Wang; D.H. Wang; G.W. Wang; H.G. Wang; J.C. Wang; K. Wang; Kai Wang; Kai Wang; L.P. Wang; L.Y. Wang; L.Y. Wang; R. Wang; W. Wang; X.G. Wang; X.J. Wang; X.Y. Wang; Y. Wang; Y.D. Wang; Z.H. Wang; Z.X. Wang; Zheng Wang; D.M. Wei; J.J. Wei; Y.J. Wei; T. Wen; S.S. Weng; C.Y. Wu; H.R. Wu; Q.W. Wu; S. Wu; X.F. Wu; Y.S. Wu; S.Q. Xi; J. Xia; J.J. Xia; G.M. Xiang; D.X. Xiao; G. Xiao; Y.F. Xiao; Y.L. Xin; H.D. Xing; Y. Xing; D.R. Xiong; B.N. Xu; C.Y. Xu; D.L. Xu; R.F. Xu; R.X. Xu; S.S. Xu; W.L. Xu; L. Xue; D.H. Yan; T. Yan; C.W. Yang; C.Y. Yang; F.F. Yang; L.L. Yang; M.J. Yang; R.Z. Yang; W.X. Yang; Z.H. Yang; Z.G. Yao; X.A. Ye; L.Q. Yin; N. Yin; X.H. You; Z.Y. You; Q. Yuan; H. Yue; H.D. Zeng; T.X. Zeng; W. Zeng; X.T. Zeng; M. Zha; B.B. Zhang; B.T. Zhang; C. Zhang; H. Zhang; H.M. Zhang; H.Y. Zhang; J.L. Zhang; J.Y. Zhang; Li Zhang; P.F. Zhang; R. Zhang; S.R. Zhang; S.S. Zhang; S.Y. Zhang; W. Zhang; W.Y. Zhang; X. Zhang; X.P. Zhang; Yi Zhang; Yong Zhang; Z.P. Zhang; J. Zhao; L. Zhao; L.Z. Zhao; S.P. Zhao; X.H. Zhao; Z.H. Zhao; F. Zheng; T.C. Zheng; B. Zhou; H. Zhou; J.N. Zhou; M. Zhou; P. Zhou; R. Zhou; X.X. Zhou; X.X. Zhou; B.Y. Zhu; C.G. Zhu; F.R. Zhu; H. Zhu; K.J. Zhu; Y.C. Zou; X. Zuo (The LHAASO Collaboration); and B. Li

arXiv:2409.09499·astro-ph.HE·January 7, 2026

Deep view of Composite SNR CTA1 with LHAASO in $\gamma$-rays up to 300 TeV

Zhen Cao, F. Aharonian, Y.X. Bai, Y.W. Bao, D. Bastieri, X.J. Bi, Y.J. Bi, W. Bian, J. Blunier, A.V. Bukevich, C.M. Cai, Y.Y. Cai, W.Y. Cao, Zhe Cao, J. Chang, J.F. Chang, E.S. Chen, G.H. Chen, H.K. Chen, L.F. Chen, Liang Chen, Long Chen, M.J. Chen, M.L. Chen, Q.H. Chen, S. Chen

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TL;DR

This study analyzes ultra-high-energy gamma-ray emissions from the composite SNR CTA1 associated with 1LHAASO J0007+7303u, revealing detailed spectral and spatial properties up to 300 TeV, and providing insights into particle acceleration in pulsar wind nebulae.

Contribution

The paper presents the first detailed analysis of UHE gamma-ray emission from CTA1 with spatial resolution and spectral modeling up to 300 TeV, linking gamma-ray data with PWN particle acceleration.

Findings

01

Detection of gamma-ray emission with high significance at 8-100 TeV and >100 TeV.

02

Determination of source extension and spectral cutoff energy.

03

Implication of advection-dominated particle transport in the PWN.

Abstract

The ultra-high-energy (UHE) gamma-ray source 1LHAASO J0007+7303u is positionally associated with the composite SNR CTA1 that is located at high Galactic Latitude $b \approx 10. 5^{\circ}$ . This provides a rare opportunity to spatially resolve the component of the pulsar wind nebula (PWN) and supernova remnant (SNR) at UHE. This paper conducted a dedicated data analysis of 1LHAASO J0007+7303u using the data collected from December 2019 to July 2023. This source is well detected with significances of 21 $σ$ and 17 $σ$ at 8 $-$ 100 TeV and $>$ 100 TeV, respectively. The corresponding extensions are determined to be 0.23 $^{\circ} \pm$ 0.03 $^{\circ}$ and 0.17 $^{\circ} \pm$ 0.03 $^{\circ}$ . The emission is proposed to originate from the relativistic electrons and positrons accelerated within the PWN of PSR J0007+7303. The energy spectrum is well described by a power-law with an exponential cutoff…

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Taxonomy

TopicsParticle physics theoretical and experimental studies · Medical Imaging Techniques and Applications · Radiation Detection and Scintillator Technologies