An analytical study on the multi-critical behaviour and related bifurcation phenomena for relativistic black hole accretion

Agarwal, Shivani; Das, Tapas K.; Dey, Rukmini; Nag, Sankhasubhra

doi:10.1007/s10714-012-1358-z

Cited by 6 publications

(4 citation statements)

References 46 publications

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“…Now, these polynomials as will be shown in the subsequent sections are usually (except in a few special cases) of order n > 4 and hence, not analytically solvable. So, in order to obtain the number of real roots of the polynomial equations for a specified range of parameters within relevant astrophysical domain 3 , we need to use the Sturm method that we discussed earlier ( [14]).…”

Section: Cp CVmentioning

confidence: 99%

“…Aforementioned papers have already solved them numerically and described the whole process from a semi-analytical approach. Very recently, a technique is developed [14] using Sturm analysis which gives us exact number of physically acceptable solutions (for which the critical points form outside the horizon) of a n-th order algebraic polynomial(of critical points) for a set of initial conditions. So, this method will help us to investigate the multi-transonicity of a general relativistic flow onto a Schwarzschild black hole completely analytically, and to get a real flavour of multi-transonic 1 except when the accreting matter starts supersonically from a reasonably large distance.…”

Section: Introductionmentioning

confidence: 99%

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Multi-criticality and related bifurcation in accretion discs around non-rotating black holes -- an analytical study

Mitra¹,

Aishee²,

Tarafdar³

et al. 2021

Preprint

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Low angular momentum, general relativistic, axially symmetric accretion of hydrodynamic fluid onto Schwarzschild black holes may undergo more than one critical transition. To obtain the stationary integral solutions corresponding to such multicritical accretion flow, one needs to employ numerical solutions of the corresponding fluid dynamics equations. In the present work, we develop a completely analytical solution scheme which may be used to find several trans-critical flow behaviours of aforementioned accretion, without explicitly solving the flow equations numerically.We study all possible geometric configurations of the flow profile, governed by all possible thermodynamic equations of state. We use Sturm's chain algorithm to find out

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Section: Cp CVmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multi-criticality and related bifurcation in accretion discs around non-rotating black holes -- an analytical study

Mitra¹,

Aishee²,

Tarafdar³

et al. 2021

Preprint

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“…However, the number of roots of such equations lying between infinity and the event horizons can be estimated analytically using the generalized Sturm sequence algorithm. 87 The expressions for the critical values of (du/dr) and (dc s /dr) have been provided in the appendix.…”

Section: Conical Flow Modelmentioning

confidence: 99%

Dependence of acoustic surface gravity on geometric configuration of matter for axially symmetric background flows in the Schwarzschild metric ~

Tarafdar¹,

Das²

2013

Preprint

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In black hole evaporation process, the mass of the hole anti-correlates with the Hawking temperature. This indicates that the smaller holes have higher surface gravity. For analogue Hawking effects, however, the acoustic surface gravity is determined by the local values of the dynamical velocity of the stationary background fluid flow and the speed of propagation of the characteristic perturbation embedded in the background fluid, as well as by their space derivatives evaluated along the direction normal to the acoustic horizon, respectively. The mass of the analogue system -whether classical or quantum -does not directly contribute to extremise the value of the associated acoustic surface gravity. For general relativistic axially symmetric background fluid flow in the Schwarzschild metric, we show that the initial boundary conditions describing such accretion influence the maximization scheme of the acoustic surface gravity and associated analogue temperature. Aforementioned background flow onto black holes can assume three distinct geometric configurations. Identical set of initial boundary conditions can lead to entirely different phase-space behavior of the stationary flow solutions, as well as the salient features of the associated relativistic acoustic geometry. This implies that it is imperative to investigate how the measure of the acoustic surface gravity corresponding to the accreting black holes gets influenced by the geometric configuration of the inflow described by various thermodynamic equations of state. Such investigation is useful to study the effect of Einstenian gravity on the non-conventional classical features as observed in Hawking like effect in a dispersive medium in the limit of a strong dispersion relation.

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“…The critical points are obtained using the critical point analysis method -a technique borrowed from the dynamical systems theory. For many of the accretion scenarios, it may be possible to locate the critical points analytically (see (Agarwal et al, 2012) and references therein). Using certain eigenvalue techniques, one becomes able to gain, completely analytically, qualitative ideas about the phase portrait of the transonic flow structure close to the critical point (Ray, 2003;Chaudhury et al, 2006;Goswami et al, 2007;Chaverra et al, 2016;Mandal et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Effective sound speed in relativistic accretion discs around Schwarzschild black holes

Shaikh¹,

Maity²,

Nag³

et al. 2019

New Astronomy

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For low angular momentum axially symmetric accretion flow maintained in hydrostatic equilibrium along the vertical direction, the value of the Mach number at the critical points deviates from unity, resulting in the non-isomorphism of the critical and the sonic points. This introduces several undesirable complexities while analytically dealing with the stationary integral accretion solutions and the corresponding phase portraits. We propose that the introduction of an effective dynamical sound speed may resolve the issue in an elegant way. We linear perturb the full spacetime-dependent general relativistic Euler and the continuity equations governing the structure and the dynamics of accretion disc in vertical equilibrium around Schwarzschild black holes and identify the sonic metric embedded within the stationary background flow. Such metric describes the propagation of the linear acoustic perturbation inside the accretion flow. We construct the wave equation corresponding to that acoustic perturbation and find the speed of propagation of such perturbation. We finally show that the ordinary thermodynamic sound speed should be substituted by the speed of propagation of the linear acoustic wave which has been obtained through the dynamical perturbation. Such substitution will make the value of Mach number at the critical point to be equal to unity. Use of the aforementioned effective sound speed will lead to a modified stationary disc structure where the critical and the sonic points will be identical.

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An analytical study on the multi-critical behaviour and related bifurcation phenomena for relativistic black hole accretion

Cited by 6 publications

References 46 publications

Multi-criticality and related bifurcation in accretion discs around non-rotating black holes -- an analytical study

Multi-criticality and related bifurcation in accretion discs around non-rotating black holes -- an analytical study

Dependence of acoustic surface gravity on geometric configuration of matter for axially symmetric background flows in the Schwarzschild metric ~

Effective sound speed in relativistic accretion discs around Schwarzschild black holes

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