Transition density of the large mass hyperon star

ZHAO Xian-Feng; JIA Huan-Yu

doi:10.1088/1674-1137/38/1/015101

Chinese Physics C> 2014, Vol. 38> Issue(1) : 015101 DOI: 10.1088/1674-1137/38/1/015101

Transition density of the large mass hyperon star

ZHAO Xian-Feng ^, ,
JIA Huan-Yu

Abstract
HTML
Reference
Related

PDF

Abstract：
The difference between the transition density of a larger mass hyperon star (for example, the neutron star PSR J1614-2230) and that of a smaller mass hyperon star is investigated in the framework of the relativistic mean field theory. We see that the transition density ρ_0H increases with the increase of x_ω (i.e. the mass of the neutron star). For the nucleons parts, the neutrons make the main contribution to the transition density as the baryon density ρ=ρ_0H. With the increase of the x_ω (i.e. the mass of the neutron star), the relative particle number density of neutrons decreases while that of protons increases. For the parts of hyperons, the Λ and Ξ^- make the main contributions to the transition density as the baryon density ρ=ρ_0H. The relative particle number density of Λ decreases while that of Ξ^- increases with the increase of the x_ω (i.e. the mass of the neutron star). For the hyperons Σ^-, Σ⁰ and Σ^-, the total contributions are less than 16 per cent.

References

[1]

Glendenning N K. Compact Stars: Nuclear Physics, Particle Physics, and General Relativity. 2nd ed. Springer, 2000[2] Glendenning N K. Astrophy, 1985, 293: 470-493[3] JIA Huan-Yu, SUN Bao-Xi, MENG Jie et al. Chin. Phys. Lett., 2001, 18: 1571-1574[4] ZHAO Xian-Feng, ZHANG Hua. Chin. Phys. C (HEP NP), 2010, 34: 1704-1708[5] Demorest P B, Pennucci T, Ransom S M et al. Nature, 2010, 467: 1081-1083[6] Massot #278;, Margueron J, Chanfray G. Europhysics Letters, 2012, 97(3): 39002[7] Weissenborn S, Chatterjee D, Schaffner-Bielich J. Phys. Rev. C, 2012, 85(6): 065802[8] Masuda K, Hatsuda T, Takatsuka T. Ap. J, 2012, 764(1): 12[9] Whittenbury D L, Carroll J D, Thomas A W, Tsushima K, Stone J R. eprint arXiv: 1204.2614(2012)[10] Mallick R. Phys. Rev. C, 2013, 87(2): 025804[11] Bednarek I, Haensel P, Zdunik J L, Bejger M, Mańka R. Astronomy Astrophysics, 2012, 543: A157[12] Katayama T, Miyatsu T, Saito K. Ap.J S, 2012, 203(2): 22[13] Weissenborn S, Chatterjee D, Schaffner-Bielich J. Nucl. Phys. A, 2012, 881: 62-77[14] JIANG Wei-Zhou, LI Bao-An, CHEN Lie-Wen. Ap. J., 2012, 756: 56[15] Chamel N, Fantina A F, Pearson J M, Goriely S. eprint arXiv: 1205.0983(2012)[16] ZHAO Xian-Feng, JIA Huan-Yu. Phys. Rev. C, 2012, 85: 065806[17] Schaffner J, Mishustin I N. Phys. Rev. C, 1996, 53: 1416-1429[18] Glendenning N K, Moszkowski S A. Phys. Rev. Lett., 1991, 67: 2414-2417[19] TAN Yu-Hong, SUN Bao-Xi, LI Lei et al. Theor. Phys., 2004, 41: 441-446[20] Dover C B, Millener D J, Gal A. Phys. Rep., 1989, 184: 1-97[21] Friedman E, Gal A. Phys. Rep., 2007, 452: 89-153[22] Batty C J, Friedman E, Gal A. Phys. Lett. B, 1994, 335: 273-278[23] Bart S, Chrien R E, Franklin W A et al. Phys. Rev. Lett., 1999, 83: 5238-5241[24] Khaustov P, Alburger D E, Barnes P D et al. Phys. Rev. C, 2000, 61: 054603[25] Fukuda T, Higashi A, Matsuyama Y et al. Phys. Rev. C, 1998, 58: 1306-1309[26] Dover C B, Gal A. Ann. Phys., 1983, 146: 309-348

[1]	Yanyan Bu , Shu Lin . Holographic magnetized chiral density wave. Chinese Physics C, 2018, 42(11): 114104. doi: 10.1088/1674-1137/42/11/114104
[2]	Kai-Wen Li , Xiu-Lei Ren , Li-Sheng Geng , Bing-Wei Long . Leading order relativistic hyperon-nucleon interactions in chiral effective field theory. Chinese Physics C, 2018, 42(1): 014105. doi: 10.1088/1674-1137/42/1/014105
[3]	Gaoqing Cao , Lianyi He , Xu-Guang Huang . Quarksonic matter at high isospin density. Chinese Physics C, 2017, 41(5): 051001. doi: 10.1088/1674-1137/41/5/051001
[4]	HOU Jia-Xun , PENG Guang-Xiong , XIA Cheng-Jun , XU Jian-Feng . Magnetized strange quark matter in a mass-density-dependent model. Chinese Physics C, 2015, 39(1): 015101. doi: 10.1088/1674-1137/39/1/015101
[5]	LI Zhao-Xi , LI Zhi-Pan . Center-of-mass correction and rotational correction in covariant density functional theory. Chinese Physics C, 2015, 39(11): 114101. doi: 10.1088/1674-1137/39/11/114101
[6]	WANG Rui , CHEN Ying , GONG Ming , LIU Chuan , LIU Yu-Bin , LIU Zhao-Feng , MA Jian-Ping , MENG Xiang-Fei , ZHANG Jian-Bo . Phase transition in finite density and temperature lattice QCD. Chinese Physics C, 2015, 39(6): 063103. doi: 10.1088/1674-1137/39/6/063103
[7]	WENG Ming-Hua , GUO Xin-Heng , LIU Bo . Vacuum fluctuation effects on hyperonic neutron star matter. Chinese Physics C, 2013, 37(12): 125101. doi: 10.1088/1674-1137/37/12/125101
[8]	DING Wen-Bo , YU Zi , MI Geng , WANG Chun-Yan . Neutron star cooling in various sets of nucleon coupling constants. Chinese Physics C, 2013, 37(5): 055101. doi: 10.1088/1674-1137/37/5/055101
[9]	Zafar Yasin , Warda Iram , Ikram Shahzad . Mass dependence of pion-induced fission cross sections on the level density parameter. Chinese Physics C, 2012, 36(9): 831-835. doi: 10.1088/1674-1137/36/9/007
[10]	XU Xiao-Mei , FU Yong-Ping , LI Yun-De . η string formation in QCD chiral phase transition. Chinese Physics C, 2010, 34(4): 444-447. doi: 10.1088/1674-1137/34/4/004
[11]	ZHAO Xian-Feng , ZHANG Hua , JIA Huan-Yu . On the moment of inertia of a proto neutron star. Chinese Physics C, 2010, 34(10): 1587-1592. doi: 10.1088/1674-1137/34/10/007
[12]	ZHONG Xian-Hui , ZHAO Qiang . K^－p scattering and hyperon excitations in a chiral quark model. Chinese Physics C, 2010, 34(9): 1428-1432. doi: 10.1088/1674-1137/34/9/062
[13]	ZHAO Xian-Feng , ZHANG Hua . Effect of the mesons σ^* and Φ and the variety of U_Σ^(N) on the transition density of hyperon stars. Chinese Physics C, 2010, 34(11): 1704-1708. doi: 10.1088/1674-1137/34/11/007
[14]	LIU Ying-Xin , QIN Shan , WU Jing , LI Xiao-Dong , LI Yan-Chun , LIU Jing . Pressure-induced phase transition of wulfenite. Chinese Physics C, 2009, 33(11): 1023-1027. doi: 10.1088/1674-1137/33/11/019
[15]	SUN Bao-Yuan , MENG Jie . Neutron star equation of state in density dependent relativistic Hartree-Fock theory. Chinese Physics C, 2009, 33(S1): 73-75. doi: 10.1088/1674-1137/33/S1/024
[16]	LI Ang , PENG Guang-Xiong , Lombardo U . Deconfinement phase transition in neutron star matter. Chinese Physics C, 2009, 33(S1): 61-63. doi: 10.1088/1674-1137/33/S1/020
[17]	YUE Peng , SHEN Hong . Antikaon condensation in neutron star matter with strong magnetic fields. Chinese Physics C, 2008, 32(S2): 85-88.
[18]	RUAN Li-Juan , WU Jian , DONG Xin , SHAO Ming , CHEN Hong-Fang , WANG Xiao-Lian , LI Cheng , HUANG Sheng-Li . The Calibration Method of TOFr in the STAR Experiment. Chinese Physics C, 2005, 29(2): 157-161.
[19]	JIA Huan-Yu , MENG Jie , ZHAO En-Guang , LI Jun , SANG Jian-Ping . Effect of Temperature on Hyperon Neutron Star. Chinese Physics C, 2003, 27(3): 200-205.
[20]	Wu Chongshi , Zeng Jinyan . Nuclear Pairing Phase Transition. Chinese Physics C, 1988, 12(S1): 81-90.

Access

Get Citation

ZHAO Xian-Feng and JIA Huan-Yu. Transition density of the large mass hyperon star[J]. Chinese Physics C, 2014, 38(1): 015101. doi: 10.1088/1674-1137/38/1/015101

ZHAO Xian-Feng and JIA Huan-Yu. Transition density of the large mass hyperon star[J]. Chinese Physics C, 2014, 38(1): 015101. doi: 10.1088/1674-1137/38/1/015101 shu

RIS(for EndNote,Reference Manager,ProCite)

BibTex

Txt

Milestone

Received: 2012-12-03
Revised: 1900-01-01

Article Metric

Article Views(1800)
PDF Downloads(201)
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

Transition density of the large mass hyperon star

Corresponding author: ZHAO Xian-Feng,

Received Date: 2012-12-03

Accepted Date: 1900-01-01

Available Online: 2014-01-05

Abstract: The difference between the transition density of a larger mass hyperon star (for example, the neutron star PSR J1614-2230) and that of a smaller mass hyperon star is investigated in the framework of the relativistic mean field theory. We see that the transition density ρ_0H increases with the increase of x_ω (i.e. the mass of the neutron star). For the nucleons parts, the neutrons make the main contribution to the transition density as the baryon density ρ=ρ_0H. With the increase of the x_ω (i.e. the mass of the neutron star), the relative particle number density of neutrons decreases while that of protons increases. For the parts of hyperons, the Λ and Ξ^- make the main contributions to the transition density as the baryon density ρ=ρ_0H. The relative particle number density of Λ decreases while that of Ξ^- increases with the increase of the x_ω (i.e. the mass of the neutron star). For the hyperons Σ^-, Σ⁰ and Σ^-, the total contributions are less than 16 per cent.

HTML

Reference (1)

Transition density of the large mass hyperon star

Abstract：

References

Access

Article Metrics

Metrics

通讯作者: 陈斌, bchen63@163.com

Email This Article