Damghan University
Astronomical Society of Iran
Iranian Journal of Astronomy and Astrophysics
2322-4924
2383-403X
6
1
2019
03
01
The phase transition of corrected black hole with f(R) gravity
1
8
EN
Mohammad
Rostami
Department of Physics&lrm;, &lrm;North Tehran Branch&lrm;, &lrm;Islamic Azad University&lrm;, &lrm;Tehran&lrm;, &lrm;Iran.
m.rostami@iau-tnb.ac.ir
Jafar
Sadeghi
Department of Physics, University of Mazandaran
pouriya@ipm.ir
Sedigheh
Mirabotalebi
Department of Physics, North Tehran Branch, Islamic Azad University, Tehran, Iran.
s_mirabotalebi@iau-tnb.ac.ir
Amir Ali
Masoudi
Department of Physics, Alzahra University, Tehran, Iran.
masoudi@alzahra.ac.ir
10.22128/ijaa.2019.342.1055
In this letter, we consider static black hole in f(R) gravity.<br />We take advantage from corrected entropy and temperature and investigate such black hole. Finally, we study the $ P - V $ critically and phase transition of corrected black hole with respect to entropy and temperature. Here also, we obtain the heat capacity for the static black hole in $ f(R) $ gravity. This calculation help us to investigate some singularity.<br />We have shown that the corrections exist for any black hole, but they are important for a small black holes and negligible for the large black holes. The advantage of a static black hole in $ f(R) $ gravity is its holographic picture, which is a van der Waals fluid. Then, We have shown that in the presence of corrections there is still a van der Waals fluid as a dual picture.<br />The critical values of event horizon radius for phase transitions are shown due to the corrections of entropy and temperature.<br />We have some figures which show the phase transition and $ P - V $ critically.
The static black hole,Phase transition,Van der Waals behavior,corrected of entropy and temperature
http://ijaa.du.ac.ir/article_152.html
http://ijaa.du.ac.ir/article_152_e26cb129b4163749762fc63251538928.pdf
Damghan University
Astronomical Society of Iran
Iranian Journal of Astronomy and Astrophysics
2322-4924
2383-403X
6
1
2019
03
01
Different Magnetic Field Distributions in Deformed Neutron Stars
9
23
EN
Mina
Zamani
Department of Physics, University of Zanjan
m_zamani@znu.ac.ir
Mohsen
Bigdeli
Department of Physics, University of Zanjan
m_bigdeli@znu.ac.ir
10.22128/ijaa.2019.343.1056
In this work, we review the formalism which would allow us to model magnetically deformed neutron stars. We study the effect of different magnetic field configurations on the equation of state (EoS) and the structure of such stars. For this aim, the EoS of magnetars is acquired by using the lowest order constraint variational (LOCV) method and employing the AV<sub>18</sub> potential. <br />We show how the magnetic field varies from the surface to the center of neutron star by using various exponential and polynomial profiles and compare their results.<br />In addition, global properties of neutron stars are obtained within two formalisms. The first formalism is described by considering the pressure into two directions and the deformation of neutron stars is governed by anisotropies in the equation of state. The second formalism for investigating macroscopic properties of magnetars is gained by treating the nonuniform pressure as a perturbation to the total pressure and expanding metric and pressure up to the quadrupole term in spherical harmonics.<br />Afterwards, we include three nucleon interactions (TNI) to the EoS and apply this model to represent our results for both exponential and polynomial magnetic field profiles.<br />The maximum gravitational mass is obtained in the range of (1.71-1.80) M<sub>.</sub> and (2.13-2.19) M<sub>.</sub> for the EoS without and with TNI contribution, respectively.
magnetars,magnetic field profiles,deformed neutron stars
http://ijaa.du.ac.ir/article_159.html
http://ijaa.du.ac.ir/article_159_92c75c51107559c39303a2ef3b4d7369.pdf
Damghan University
Astronomical Society of Iran
Iranian Journal of Astronomy and Astrophysics
2322-4924
2383-403X
6
1
2019
03
01
Super algebra and Harmonic Oscillator in Anti de Sitter space
25
31
EN
Omid
Jalili
0000-0002-9408-174X
Department of Physics, Islamic Azad University-Nour Branch, Nour, Iran
omid_jalili@yahoo.com
Shahin
Toni
0000-0002-8386-1222
Department of Physics, Isalmic Azad University-Nour Branch, Nour, Iran
shahin.toni75@gmail.com
10.22128/ijaa.2019.344.1057
The harmonic oscillator in anti de Sitter space(AdS) is discussed. We consider the harmonic oscillator potential and then time independent Schrodinger equation in AdS space. Then we apply the supersymmetric Quantum Mechanics approach to solve our differential equation. In this paper we have solved Schrodinger equation for harmonic oscillator in AdS spacetime by supersymmetry approach. The shape invariance, charge conjugation and other properties of supersymmetric Quantum Mechanics for our equation are discussed. We investigate the dynamical symmetry into definite group. We also obtain the Casimir operator and thermodynamics properties of harmonic oscillator in Anti de sitter space. We have discussed the corresponding algebra for the N=2 Supersymmetry. The energy spectrum of the harmonic oscillator is similar to the flat space but the constant terms of it are different, This constant terms depends to the geometrical parameter of the background. Finally we have obtained the various thermodynamics quantity of the system.
Harmonic Oscillator,Anti de Sitter space,Supersymmetry,Thermal Properties
http://ijaa.du.ac.ir/article_158.html
http://ijaa.du.ac.ir/article_158_465bf23f88d017cffb70b0efc35f50d7.pdf
Damghan University
Astronomical Society of Iran
Iranian Journal of Astronomy and Astrophysics
2322-4924
2383-403X
6
1
2019
03
01
Bulk Viscous Bianchi Type VI0 Cosmological Model in the Self-creation Theory of Gravitation and in the General Theory of Relativity
33
44
EN
E. A.
Hegazy
0000-0003-3244-4629
Minia university, faculty of Science, Mathematics department, 61519 El Minia, Egypt.
sayed00ali@gmail.com
10.22128/ijaa.2019.345.1058
In the second self-creation theory of gravitation and in the general theory of relativity, Bianchi type VI<sub>0</sub> cosmological model in the presence of viscous fluid is studied. An exact solution of the field equations is given by considering the cosmological model yields a constant decelerations parameter q=constant and the coefficients of the metric are taken as A(t)=[c<sub>1</sub>t+c<sub>2</sub>]3L/(q+1)(L+1), B(t)=[c<sub>1</sub>t+c<sub>2</sub>]3/2(q+1)(L+1),C(t)=[c<sub>1</sub> t+ c<sub>2</sub>]3/2(q+1)(L+1),where c<sub>1</sub>,c<sub>2</sub> and L are constants . Effect of the viscosity on the entropy of the universe is given by a composition of the second law of thermodynamics with the the energy momentum tensor T<sub>j</sub><sup>i</sup> with bulk viscous term in a conservative manner. We obtained a formula for calculation the entropy of the universe in term of the viscosity and used it to study and compare the Entropy, Enthalpy, Gibbs energy and Helmholtz energy of the universe in the presence of viscosity term in the self-creation theory of gravitation and in the general theory of relativity. The physical and geometrical properties of the obtained models are discussed.
General theory of relativity,Einstein field equations,Bianchi type VI$_0$ cosmological models,Viscosity,Entropy
http://ijaa.du.ac.ir/article_160.html
http://ijaa.du.ac.ir/article_160_2327cc011977eef2cc5a380d82267e83.pdf
Damghan University
Astronomical Society of Iran
Iranian Journal of Astronomy and Astrophysics
2322-4924
2383-403X
6
1
2019
03
01
The braneworld stability and large-scale correction in graphene like background
45
52
EN
Zahra
Zali
Department of Physics, Islamic Azad University, Ayatollah Amoli Branch
st.z.zali@iauamol.ac.ir
Jafar
Sadeghi
Department of Physics, University of Mazandaran
pouriya@ipm.ir
Behnam
Pourhassan
0000-0003-1338-7083
School of Physics, University of Damghan, Damghan, Iran
b.pourhassan@du.ac.ir
10.22128/ijaa.2019.335.1051
In this work, we consider a graphene-like background in braneworld scenario which is one of the interesting models in cosmology and theoretical physics. Indeed, this paper is an application of holography in condense matter. We use the geometric form of potential which help to obtain field equations and solve it to obtain the energy spectrum. In that case we calculate superpotential and energy density of this model. Thermodynamical study of this model suggest that the entropy should modified due to the large-scale corrections. An important point is stability of this model in braneworld scenario. We study model stability by two separated methods. We calculate heat capacity, Gibbs and Helmholtz free energy to analyze thermodynamics stability, then consider small perturbations in graphene like metric background to investigate gravitational stability. We find that the model is completely stable unless in very low temperatures where the graphene structure may break. Hence, we confirm that our braneworld model is thermodynamically stable and also small perturbations yields to an oscillation around the equilibrium point.
stability,Perturbations,Graphene,Thermodynamics,Braneworld
http://ijaa.du.ac.ir/article_161.html
http://ijaa.du.ac.ir/article_161_c007483ab819d8239d4e44a9118b8656.pdf
Damghan University
Astronomical Society of Iran
Iranian Journal of Astronomy and Astrophysics
2322-4924
2383-403X
6
1
2019
03
01
The Isaac Newton Telescope Monitoring project: Stellar population in the IC 10 dwarf irregular galaxy
53
70
EN
Mahtab
Gholami
Department of Physics, Alzahra University,
Tehran, P.O.Box 1993891176, Iran
m.gholami@alzahra.ac.ir
Mohammad Taghi
Mirtorabi
Department of Physics, Alzahra University,
Tehran, P.O.Box 1993891176, Iran
torabi@alzahra.ac.ir
10.22128/ijaa.2020.348.1060
We have conducted an optical monitoring survey of IC 10 dwarf irregular galaxy in the Local Group, using the Isaac Newton Telescope (INT) with the wide-field camera (WFC), to identify the Asymptotic Giant Branch stars (AGBs). AGBs are at the final stage of their evolution and can be implemented as powerful tools for finding the star formation history and chemical evolution of galaxies. The stellar populations in IC 10 had not been previously identified in optical wavebands surveys. Our data set was obtained in the i- and V-band with the WFC instrument. Photometry was obtained for 48578 stars within the area of 0.07 deg^2 (13.5 kpc^2), of which 10800 stars are detected as AGBs. Radial distribution histogram has been constructed in the image plane for populations of AGBs, RGBs (Red Giant Branch stars) and massive stars. We found that the RGBs population has the largest effective radius among the three populations in the IC 10 image plane. Our data were matched to optical catalogues of Pan-STARRS (The Pan-STARRS release 1 (PS1) survey-DR1) catalogue, mid-infrared catalogue of good sources (DUSTiNGS Good Source Catalog (GSC)) from the Spitzer Space Telescope and near-IR catalogue of Hubble Space Telescope (HST). The number of 441 and 1927 were identified as C-type (carbon-rich) and M-type (oxygen-rich) stars respectively; using the matched stars between our catalogue and the HST catalogue.
Stars: AGB,RSG,RGB,galaxies: Irregular,dwarf
http://ijaa.du.ac.ir/article_162.html
http://ijaa.du.ac.ir/article_162_4d1d9ab3f3869aa058b7f03ae3312ab3.pdf