Low angular momentum relativistic hot accretion flow around Kerr black holes with variable adiabatic index

Dihingia, Indu Kalpa; Das, Santabrata; Nandi, Anuj

doi:10.1093/mnras/stz168

Cited by 27 publications

(22 citation statements)

References 77 publications

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“…Nevertheless, our results stay in agreement with this work for their models with Ideal EoS (IEoS) and spinless black hole with a = 0. As it is shown in Dihingia et al (2019), for different values of , λ and spin parameter a, the range of compression ratio covers the values of (R) as R max = 3.79 down to R min = 1.19. From our simulation, we get a R max = 3.88 and R min = 1.3 for model D6 with γ = 1.4 during the whole evolution of the flow.…”

Section: Correspondence To Former Modelsmentioning

confidence: 82%

See 1 more Smart Citation

Effects of adiabatic index on the sonic surface and time variability of low angular momentum accretion flows

Palit

Janiuk

Suková

2019

Monthly Notices of the Royal Astronomical Society

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We study the role of adiabatic index in determining the critical points in the transonic low angular momentum accretion flow onto a black hole. We present the general relativistic 2D hydrodynamic simulations of axisymmetric, inviscid accretion flows in a fixed Kerr black hole gravitational field. A relativistic fluid where its bulk velocity is comparable to the speed of light, flowing in the accretion disk very close to the horizon can be described by an adiabatic index of 4/3 < γ < 5/3. The time dependent evolution of the shock position and respective effects on mass accretion rate and oscillation frequency with varying adiabatic index is discussed in the context of the observed microquasars.

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Section: Correspondence To Former Modelsmentioning

confidence: 82%

“…A more recent semi-analytic work shows the effects of variable adiabatic index on shock formation and oscillation by using a relativistic EoS (Dihingia et al 2019). We note that in our code we use the adiabatic EoS with a constant γ, due to the difficulties of the conservative MHD scheme embedded in HARM.…”

Section: Correspondence To Former Modelsmentioning

confidence: 99%

Effects of adiabatic index on the sonic surface and time variability of low angular momentum accretion flows

Palit

Janiuk

Suková

2019

Monthly Notices of the Royal Astronomical Society

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“…For GRO J1655−40, the source mass is estimated using the dynamical method as MBH = 5.1 − 6.3 M⊙ (Greene, Bailyn & Orosz 2001;Beer & Podsiadlowski 2002). Interestingly, contradictory claims appear in the measurement of the spin parameter (Abramowicz & Kluźniak 2001;Shafee et al 2006;Motta et al 2014;Aktar et al 2017;Dihingia, Das & Nandi 2019) which is yet to be settled. Hence, in this work, we consider 0.8 ≤ a k ≤ 0.99 for representation and calculate ν max QP O as before.…”

Section: Accretion Solution With Shockmentioning

confidence: 99%

“…After the shock transition, flow momentarily slows down, however, gradually picks its radial velocity as it moves inward and ultimately enters into the black hole after crossing another critical point usually located close to the horizon. This renders the complete shock induced global accretion solution and solutions of this kind have been examined by several researchers (Fukue 1987;Chakrabarti 1989;Yang & Kafatos 1995;Lu, Gu & Yuan 1999;Becker & Kazanas 2001;Fukumura & Tsuruta 2004;Chakrabarti & Das 2004;Das 2007;Sarkar & Das 2016;Dihingia, Das & Mandal 2018a,b;Dihingia, Das & Nandi 2019). Due to shock compression, post-shock flow becomes hot and dense that results a puffed up torus like structure surrounding the black hole which is equivalently called as post-shock corona (hereafter PSC) (Aktar, Das & Nandi 2015).…”

Section: Introductionmentioning

confidence: 99%

Shocks in relativistic viscous accretion flows around Kerr black holes

Dihingia,

Das,

Maity

et al. 2019

Preprint

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We study the relativistic viscous accretion flows around the Kerr black holes. We present the governing equations that describe the steady state flow motion in full general relativity and solve them in 1.5D to obtain the complete set of global transonic solutions in terms of the flow parameters, namely specific energy (E ), specific angular momentum (L ) and viscosity (α). We obtain a new type of accretion solution which was not reported earlier. Further, we show for the first time to the best of our knowledge that viscous accretion solutions may contain shock waves particularly when flow simultaneously passes through both inner critical point (r in ) and outer critical point (r out ) before entering into the Kerr black holes. We examine the shock properties, namely shock location (r s ) and compression ratio (R, the measure of density compression across the shock front) and show that shock can form for a large region of parameter space in L − E plane. We study the effect of viscous dissipation on the shock parameter space and find that parameter space shrinks as α is increased. We also calculate the critical viscosity parameter (α cri ) beyond which standing shock solutions disappear and examine the correlation between the black hole spin (a k ) and α cri . Finally, the relevance of our work is conferred where, using r s and R, we empirically estimate the oscillation frequency of the shock front (ν QP O ) when it exhibits Quasiperiodic (QP) variations. The obtained results indicate that the present formalism seems to be potentially viable to account for the QPO frequency in the range starting from milli-Hz to kilo-Hz as 0.386 Hz ≤ ν QP O 10M⊙ MBH ≤ 1312 Hz for a k = 0.99, where M BH stands for the black hole mass.

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“…As a useful supplement to prevailing theory, the shocks in accretion flow, including the axisymmetric radially standing shocks and non-axisymmetric spiral shocks, have been rigorously investigated in literature over past decades. Series of theoretical works proposed and gradually improved the radially standing shock model Corresponding author: Ramiz Aktar & Li Xue ramizaktar@gmail.com, lixue@xmu.edu.cn (Fukue 1987;Chakrabarti 1989;Lu et al 1999;Becker & Kazanas 2001;Fukumura & Tsuruta 2004;Chakrabarti & Das 2004;Sarkar & Das 2016;Sarkar et al 2018;Dihingia et al 2018Dihingia et al , 2019b. This model has been used to explain the observational spectral states and quasiperiodic oscillations of compact objects (Chakrabarti & Titarchuk 1995;Molteni et al 1996).…”

Section: Introductionmentioning

confidence: 99%

Point-wise Self-similar Solution for Spiral Shocks in Accretion Disk with Mass Outflow in Binary

Aktar,

Xue,

Liu

2021

Preprint

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We examine the properties of spiral shocks from a steady, adiabatic, non-axisymmetric accretion disk around a compact star in binary. We first time incorporate all the possible influences from binary through adopting the Roche potential and Coriolis forces in the basic conservation equations. In this paper, we assume the spiral shocks to be point-wise self-similar, and the flow is in vertical hydrostatic equilibrium to simplify the study. We also investigate the mass outflow due to the shock compression and apply it to the accreting white dwarf in binary. We find that our model will be beneficial to overcome the ad hoc assumption of optically thick wind generally used in the studies of the progenitor of supernovae Ia.

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Low angular momentum relativistic hot accretion flow around Kerr black holes with variable adiabatic index

Cited by 27 publications

References 77 publications

Effects of adiabatic index on the sonic surface and time variability of low angular momentum accretion flows

Effects of adiabatic index on the sonic surface and time variability of low angular momentum accretion flows

Shocks in relativistic viscous accretion flows around Kerr black holes

Point-wise Self-similar Solution for Spiral Shocks in Accretion Disk with Mass Outflow in Binary

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