Evolving Horava cosmological horizons

Mohsen Fathi; Morteza Mohseni

doi:10.1088/1674-1137/40/9/095101

Chinese Physics C> 2016, Vol. 40> Issue(9) : 095101 DOI: 10.1088/1674-1137/40/9/095101

Evolving Horava cosmological horizons

Mohsen Fathi ^, ,
Morteza Mohseni ^,

1.
Department of Physics, Payame Noor University (PNU), P. O. Box 19395-3697 Tehran, I. R. of Iran

Abstract
HTML
Reference
Related

PDF

Abstract：
Several sets of radially propagating null congruence generators are exploited in order to form 3-dimensional marginally trapped surfaces, referred to as black hole and cosmological apparent horizons in a Hořava universe. Based on this method, we deal with the characteristics of the 2-dimensional space-like spheres of symmetry and the peculiarities of having trapping horizons. Moreover, we apply this method in standard expanding and contracting FLRW cosmological models of a Hořava universe to investigate the conditions under which the extra parameters of the theory may lead to trapped/anti-trapped surfaces both in the future and in the past. We also include the cases of negative time, referred to as the finite past, and discuss the formation of anti-trapped surfaces inside the cosmological apparent horizons.
- Hořava universe ,
- standard cosmology ,
- null congruence expansion ,
- black hole horizons ,
- white holes

References

[1]	P. Horava, Physical Review D, 79:084008(2009)
[2]	C. Charmousis, G. Niz, A. Padilla, P. M. Saffin, Journal of High Energy Physics, 08:070(2009)
[3]	S. Weinfurtner, T. P. Sotiriou, M. Visser, Journal of Physics:Conference Series, 222:012054(2010)
[4]	K. Koyama, F. Arroja, Journal of High Energy Phsyics, 03:061(2010)
[5]	D. Blas, O. Pujols, S. Sibiryakov, Journal of High Energy Physics, 10:029(2009)
[6]	D. Blas, O. Pujols, S. Sibiryakov, Physical Review Letters, 104:181302(2010)
[7]	J. Klusoň, Physical Review D, 82:044004(2010)
[8]	J. Klusoň, Journal of High Energy Physics, 07:038(2010)
[9]	P. Horava, C. M. Melby-Thompson, Physical Review D, 82:064027(2010)
[10]	J. Klusoň, S. Nojiri, S. D. Odintsov, D. Sez-Gmez, European Physical Journal C, 71:1690(2011)
[11]	J. Klusoň, European Physical Journal C, 71:1820(2011)
[12]	T. Griffin, P. Horava, C. M. Melby-Thompson, Physical Review Letters, 110:081602(2013)
[13]	M. Chaichian, J. Klusoň, M. Oksanen, Physical Review D, 92:104043(2015)
[14]	A. O. Barvinsky, D. Blas, M. Herrero-Valea, S. M. Sibiryakov, C. F. Steinwachs, Physical Review D, 93:064022(2016)
[15]	M.I. Park, Journal of High Energy Physics, 0909:123(2009)
[16]	A. Kehagias, K. Sfetsos, Physics Letters B, 678:123(2009)
[17]	H. Lu, J. Mei, C.N. Pope, Physical Review Letters, 103:091301(2009)
[18]	C. Capasso, Physical Review D, 82:124058(2010)
[19]	R-G. Cai, S. P. Kim, JHEP, 0502:050(2005)
[20]	R-G. Cai, L-M. Cao, Y-P Hu, Class. Quant. Grav., 26:155018(2009)
[21]	R-G. Cai, L-M. Cao, N. Ohta, Phys. Rev. D, 80:024003(2009)
[22]	R-G. Cai, L-M. Cao, N. Ohta, Physics Letters B, 679:504(2009)
[23]	R-G. Cai, N. Ohta, Physical Review D, 81:084061(2010)
[24]	I. Radinschi, F. Rahaman, A. Banerjee, International Journal of Theoretical Physics, 50:2906(2011)
[25]	I. Radinschi, F. Rahaman, A. Banerjee, International Journal of Theoretical Physics, 51:1425(2012)
[26]	J. Chen, Y. Wang, International Journal of Modern Physics A, 25 (7):1439(2010)
[27]	A. Abdujabbarov, B. Ahmedov, A. Hakimov, Physical Review D, 83:044053(2011)
[28]	J. Sadeghi, B. Pourhassan, The European Physical Journal C, 72:1984(2012)
[29]	R. Penrose, Physical Review Letters, 14:57(1965)
[30]	S. W. Hawking, R. Penrose, Proceedings of the Royal Society A, 314:529(1970)
[31]	E. Barausse, T. Jacobson, T. P. Sotiriou, Physical Review D, 83:124043(2011)
[32]	E. Abdalla, N. Afshordi, M. Fontanini, Physical Review D, 89:104018(2014)
[33]	M. Saravani, N. Afshordi, R.B. Mann, Physical Review D, 89:084029(2014)
[34]	S. Mukohyama, Classical and Quantum Gravity, 27:223101(2010)
[35]	R. L. Arnowitt, S. Deser, C. W. Misner, The Dynamics of General Relativity, edited by Louis Witten:Wilew, New York (1962)
[36]	V. Faraoni, Galaxies, 1:114(2013)
[37]	E. Poisson:A Relativists Toolkit:The Mathematics of Black-Hole Mechanics (Cambridge:Cambridge University Press, UK 2004)
[38]	V. Mukhanov, Physical Foundations of Cosmology (Cambridge:Cambridge University Press, UK 2005)

[1]	. Soft pattern of gravitational Rutherford scattering from heavy target mass expansion. Chinese Physics C, 2026, 50(1): 013102. doi: 10.1088/1674-1137/ad62d6
[2]	Li Tang , Liang Liu , Ying Wu . Null test of cosmic curvature using deep learning method. Chinese Physics C, 2026, 50(2): 1-8.
[3]	. Testing Einstein-Maxwell Power-Yang-Mills hair via black hole photon rings. Chinese Physics C, 2026, 50(1): 015101. doi: 10.1088/1674-1137/ae039c
[4]	. Generation of axions and axion-like particles through mass parametric resonance induced by scalar perturbations in the early universe. Chinese Physics C, 2025, 49(12): 125108. doi: 10.1088/1674-1137/adfa82
[5]	Qi-Quan Li , Yu Zhang , Hoernisa Iminniyaz . Rotating and non-linear magnetic-charged black hole with an anisotropic matter field. Chinese Physics C, 2025, 49(10): 105106. doi: 10.1088/1674-1137/ade0a9
[6]	Lola Meliyeva , Obid Xoldorov , Olmos Tursunboyev , Shavkat Karshiboev , Sardor Murodov , Isomiddin Nishonov , Bekzod Rahmatov . Theoretical study of Strong gravitational lensing around Dyonic ModMax black hole: constraints from EHT observations. Chinese Physics C, 2025, 49(12): 125102. doi: 10.1088/1674-1137/adf4a0
[7]	Hai-Long Zhen , Huai-Fan Li , Yu-Bo Ma . Universality of thermodynamic relation with corrections in Einstein-Bel-Robinson gravity black holes. Chinese Physics C, 2025, 49(11): 111001. doi: 10.1088/1674-1137/ade6d3
[8]	Sen Yang , Yu-Peng Zhang , Tao Zhu , Li Zhao , Yu-Xiao Liu . Constraining polymerized black holes with quasi-circular extreme mass-ratio inspirals. Chinese Physics C, 2025, 49(11): 115107. doi: 10.1088/1674-1137/adef1a
[9]	Saeed Ullah Khan , Javlon Rayimbaev , Zhi-Min Chen , Zdeněk Stuchlík . Circular motion and acceleration of charged particles around magnetized rotating black holes in scalar-tensor-vector gravity. Chinese Physics C, 2025, 49(9): 095102. doi: 10.1088/1674-1137/add8fc
[10]	Xufen Zhang , De-Cheng Zou , Chao-Ming Zhang , Ming Zhang , Rui-Hong Yue . Perturbations of massless external fields on magnetically charged black holes in string-inspired Euler-Heisenberg theory. Chinese Physics C, 2025, 49(10): 105109. doi: 10.1088/1674-1137/ade661
[11]	Xiang-Qian Li , Yoonbai Kim , Bum-Hoon Lee , Hao-Peng Yan , Xiao-Jun Yue . Black holes immersed in modified Chaplygin-like dark fluid and cloud of strings: geodesics, shadows, and images. Chinese Physics C, 2025, 49(10): 105104. doi: 10.1088/1674-1137/add9fa
[12]	Erdem Sucu , İzzet Sakallı . Quantum tunneling and Aschenbach effect in nonlinear Einstein-Power-Yang-Mills AdS black holes. Chinese Physics C, 2025, 49(10): 105101. doi: 10.1088/1674-1137/add8fe
[13]	Mirjavoxir Mirkhaydarov , Mirzabek Alloqulov , Sanjar Shaymatov . Radiation properties of the accretion disk around a quantum-corrected black hole. Chinese Physics C, 2025, 49(12): 125107. doi: 10.1088/1674-1137/adfa83
[14]	De-Cheng Zou , Xufen Zhang , Chao-Ming Zhang , Ming Zhang , Rui-Hong Yue . Axial gravitational quasinormal modes of magnetically charged black holes. Chinese Physics C, 2025, 49(12): 125109. doi: 10.1088/1674-1137/adff01
[15]	Vitalii Vertogradov , Ali Övgün , Daniil Shatov . Formation of regular black hole from baryonic matter. Chinese Physics C, 2025, 49(11): 115103. doi: 10.1088/1674-1137/ade95c
[16]	Tianxu Huo , Chengzhou Liu . Corrected first law of thermodynamics for dynamical regular black holes. Chinese Physics C, 2025, 49(12): 125104. doi: 10.1088/1674-1137/adf541
[17]	Rui-Bo Wang , Lei You , Shi-Jie Ma , Jian-Bo Deng , Xian-Ru Hu . Thermodynamic phase transition and Joule-Thomson expansion of a quantum corrected black hole in AdS spacetime. Chinese Physics C, 2025, 49(11): 115102. doi: 10.1088/1674-1137/ade4a9
[18]	Zhen-Ming Xu , Bin Wu , Tao Yang , Wen-Li Yang . A new measure of thermal micro-behavior for the AdS black hole. Chinese Physics C, 2021, 45(1): 015106. doi: 10.1088/1674-1137/abc23e
[19]	Hong-Lei Li , Peng-Cheng Lu , Cong-Feng Qiao , Zong-Guo Si , Ying Wang . Study of the Standard Model and Majorana neutrino contributions to ${ B}^{{ +}} { \to} { K}^{{ (*){ \pm}}}{ \mu}^{ +}{ \mu}^{{ \mp}}$. Chinese Physics C, 2019, 43(2): 023101. doi: 10.1088/1674-1137/43/2/023101
[20]	LIANG Jun , LIU Yan-Chun , ZHU Qiao . Thermodynamics of noncommutative geometry inspired black holes based on Maxwell-Boltzmann smeared mass distribution. Chinese Physics C, 2014, 38(2): 025101. doi: 10.1088/1674-1137/38/2/025101

Access

Get Citation

Mohsen Fathi and Morteza Mohseni. Evolving Horava cosmological horizons[J]. Chinese Physics C, 2016, 40(9): 095101. doi: 10.1088/1674-1137/40/9/095101

Mohsen Fathi and Morteza Mohseni. Evolving Horava cosmological horizons[J]. Chinese Physics C, 2016, 40(9): 095101. doi: 10.1088/1674-1137/40/9/095101 shu

RIS(for EndNote,Reference Manager,ProCite)

BibTex

Txt

Milestone

Received: 2016-06-02

Article Metric

Article Views(3204)
PDF Downloads(141)
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

Evolving Horava cosmological horizons

Abstract：

References

Access

Article Metrics

Metrics

通讯作者: 陈斌, bchen63@163.com

Email This Article

Evolving Horava cosmological horizons

Corresponding author: Mohsen Fathi,

Corresponding author: Morteza Mohseni,

HTML

目录