Your search keyword '"Chakrabarti, Sandip K."' showing total 43 results

1. Accretion flow properties of GRS 1716-249 during its 2016–17 ‘failed’ outburst

Author

Chatterjee, Kaushik, Debnath, Dipak, Chatterjee, Debjit, Jana, Arghajit, Nath, Sujoy Kumar, Bhowmick, Riya, and Chakrabarti, Sandip K.

Published

2021

2. Spectral properties of shocked accretion flows— a self-consistent study

Author

Chakrabarti, Sandip K., Mandal, Samir, Paredes, Josep M., editor, Reimer, Olaf, editor, and Torres, Diego F., editor

Published

2007

3. Spectral signatures of dissipative standing shocks and mass outflow in presence of Comptonization around a black hole

Author

Mondal, Santanu, Chakrabarti, Sandip K., and Debnath, Dipak

Published

2014

4. Interaction of accretion shocks with winds

Author

Acharya, Kinsuk, Chakrabarti, Sandip K., and Molteni, D.

Published

2002

5. Standing shocks around black holes and estimation of outflow rates

Author

Das, Santabrata and Chakrabarti, Sandip K.

Published

2002

6. Inference on accretion flow properties of XTE J1752-223 during its 2009-10 outburst.

Author

Chatterjee, Kaushik, Debnath, Dipak, Chatterjee, Debjit, Jana, Arghajit, and Chakrabarti, Sandip K

Subjects

TRANSONIC flow, ACCRETION (Astrophysics), BLACK holes, FREQUENCIES of oscillating systems, X-ray binaries

Abstract

Spectral and timing properties of the stellar-mass black hole candidate XTE J1752-223 during its 2009-10 outburst are studied using RXTE PCA data in the 2.5–25 keV energy range. Low frequency quasi-periodic oscillations are seen during outburst. The spectral analysis is done using two types of models: one is the combined disc blackbody plus power-law model and the other is Transonic flow solution based Two Component Advective Flow (TCAF) model. Light-curve profiles and evolution of hardness ratios are studied using MAXI GSC and Swift BAT data. Based on the evolution of the temporal and the spectral properties, we find that the object evolved through the following spectral states: hard, hard-intermediate, and soft-intermediate/soft. From the TCAF model fitted spectral analysis, we also estimate the probable mass of the black hole in the range of 8.1−11.9 M⊙, and more precisely, the mass appears to be 10 ± 1.9 M⊙. [ABSTRACT FROM AUTHOR]

Published

2020

7. General relativistic numerical simulation of sub-Keplerian transonic accretion flows on to rotating black holes: Kerr space–time.

Author

Kim, Jinho, Garain, Sudip K, Chakrabarti, Sandip K, and Balsara, Dinshaw S

Subjects

GENERAL relativity (Physics), COMPUTER simulation, TRANSONIC aerodynamics, ACCRETION (Astrophysics), BLACK holes, DISKS (Astrophysics)

Abstract

We study time evolution of sub-Keplerian transonic accretion flows on to black holes using a general relativistic numerical simulation code. We perform simulations around the black holes having non-zero rotation. We first compare one-dimensional simulation results with theoretical results and validate the performance of our code. Next, we present results of axisymmetric, two-dimensional simulation of advective flows. In the literature, there is no solution which describes steady shock solutions in two dimensions. However, our simulations produce these centrifugal force supported steady shock waves even in presence of strong dragging of inertial frames. Since the post-shock region could be hot and upscatter photons through Comptonization, these shock would put imprints on the spectra. Thus, our solutions, which represent truly new results, could be useful to measure spins through radiation spectrum of accreting Kerr black holes. [ABSTRACT FROM AUTHOR]

Published

2019

8. Evolution of accretion disc geometry of GRS 1915+105 during its χ state as revealed by TCAF solution.

Author

Dutta, Broja G, Pal, Partha Sarathi, and Chakrabarti, Sandip K

Subjects

ACCRETION disks, ASTRONOMICAL observations, MOLECULAR clouds, PHOTONS, SHOCK waves

Abstract

The evolution of the C-type low-frequency quasi-periodic oscillations (QPOs) and associated time lag in transient black hole sources as a function of time can be explained by variation of the Compton cloud size in a two-component advective flow solution. A similar study of a persistent source, GRS 1915+105, has not been attempted. We fit the evolution of QPOs with propagatory oscillating shock solution for two sets of so-called χ-state observations and find that the shock steadily recedes with almost constant velocity when QPO frequency is decreasing and the spectrum is hardening. The shock moves inwards swith constant velocities $v$ 0 = 473.0 cm s−1 and $v$ 0 = 400.0 cm s−1, respectively, in these two cases, when the QPO frequency is increasing and the spectrum softens. This behaviour is similar to what was observed in XTE J1550−564 during the 1998 outburst. The time lag measured at the QPO frequency varies in a similar way as the size of the Compton cloud. Most interestingly, in both the cases, the lag switches sign (hard lag to soft lag) at a QPO frequency of ∼2.3−2.5 Hz irrespective of the energy of photons. We find, at very low frequencies <1 Hz, the Comptonizing efficiency (CE) increases with QPO frequency and at higher QPO frequencies the trend is opposite. The time lags become mostly positive at all energies when CE is larger than ${\sim } 0.85{{\rm \,per\,cent}}$ for both the sources. [ABSTRACT FROM AUTHOR]

Published

2018

9. Hydrodynamic simulations of accretion flows with time-varying viscosity.

Author

Roy, Abhishek and Chakrabarti, Sandip K.

Subjects

*BLACK holes, *SHOCK waves, *HYDRODYNAMICS, *MEASUREMENT of viscosity, *COMPUTER simulation, *PARAMETER estimation

Abstract

X-ray outbursts of stellar-mass black hole candidates are believed to be due to a sudden rise in viscosity, which transports angular momentum efficiently and increases the accretion rates, causing higher X-ray flux. After the viscosity is reduced, the outburst subsides and the object returns back to the pre-outburst quiescence stage. In the absence of a satisfactory understanding of the physical mechanism leading to such a sharp time dependence of viscous processes, we perform numerical simulations where we include the rise and fall of a viscosity parameter at an outer injection grid, assumed to be located at the accumulation radius where matter from the companion is piled up before being released by enhanced viscosity. We use a power-law radial dependence of the viscosity parameter (α ~ rϵ ), but the exponent (ϵ) is allowed to vary with time to mimic a fast rise and decay of the viscosity parameter. Since X-ray spectra of a black hole candidate can be explained by a Keplerian disc component in the presence of a post-shock region of an advective flow, our goal here is also to understand whether the flow configurations required to explain the spectral states of an outbursting source could be obtained by a time-varying viscosity. We present the results of our simulations to prove that low-angular-momentum (sub-Keplerian) advective flows do form a Keplerian disc in the pre-shock region when the viscosity is enhanced, which disappears on a much longer time-scale after the viscosity is withdrawn. From the variation of the Keplerian disc inside an advective halo, we believe that our result, for the first time, is able to simulate the twocomponent advective flow dynamics during an entire X-ray outburst and explain the observed hysteresis effects in the hardness-intensity diagram. [ABSTRACT FROM AUTHOR]

Published

2017

10. Monte Carlo simulations of thermal comptonization process in a two-component advective flow around a neutron star.

Author

Bhattacharjee, Ayan and Chakrabarti, Sandip K.

Subjects

*MONTE Carlo method, *NEUTRON stars, *STELLAR radiation, *ACCRETION disks, *X-ray binaries, *SHOCK waves

Abstract

We explore spectral properties of a two-component advective flow around a neutron star. We compute the effects of thermal Comptonization of soft photons emitted from a Keplerian disc and the boundary layer of the neutron star by the post-shock region of a sub-Keplerian flow, formed due to the centrifugal barrier. The shock location Xs is also the inner edge of the Keplerian disc. We compute a series of realistic spectra assuming a set of electron temperatures of the post-shock region TCE, the temperature of the Normal BOundary Layer (NBOL) TNS of the neutron star and the shock location Xs. These parameters depend on the disc and halo accretion rates (ṁd and ṁh, respectively) that control the resultant spectra. We find that the spectrum becomes harder when ṁh is increased. The spectrum is controlled strongly by TNS due to its proximity to the Comptonizing cloud since photons emitted from the NBOL cool down the post-shock region very effectively. We also show the evidence of spectral hardening as the inclination angle of the disc is increased. [ABSTRACT FROM AUTHOR]

Published

2017

11. General relativistic numerical simulation of sub-Keplerian transonic accretion flows on to black holes: Schwarzschild space-time.

Author

Jinho Kim, Garain, Sudip K., Balsara, Dinshaw S., and Chakrabarti, Sandip K.

Subjects

RELATIVISTIC particles, COMPUTER simulation, TRANSONIC aerodynamics, ACCRETION (Astrophysics), BLACK holes, SCHWARZSCHILD black holes

Abstract

We study time evolution of sub-Keplerian transonic accretion flows on to black holes using a general relativistic numerical simulation code. We perform simulations in Schwarzschild space-time. We first compare one-dimensional simulation results with theoretical results and validate the performance of our code. Next, we present results of axisymmetric, twodimensional simulation of advective flows. We find that even in this case, for which no complete theoretical analysis is present in the literature, steady-state shock formation is possible. [ABSTRACT FROM AUTHOR]

Published

2017

12. Numerical simulation of vertical oscillations in an axisymmetric thick accretion flow around a black hole.

Author

Deb, Arnab, Giri, Kinsuk, and Chakrabarti, Sandip K.

Subjects

BLACK holes, ACCRETION (Astrophysics), AXIAL flow, CENTRIFUGAL force, COMPUTER simulation, FINITE difference method

Abstract

We study time evolution of rotating, axisymmetric, two-dimensional inviscid accretion flows around black holes using a grid-based finite difference method. We do not use reflection symmetry on the equatorial plane in order to inspect if the disc along with the centrifugal barrier oscillated vertically. In the inviscid limit, we find that the CENtrifugal pressure supported BOundary Layer (CENBOL) is oscillating vertically, more so, when the specific angular momentum is higher. As a result, the rate of outflow produced from the CENBOL, also oscillates. Indeed, the outflow rates in the upper half and the lower half are found to be anticorrelated. We repeat the exercise for a series of specific angular momentum λ of the flow in order to demonstrate effects of the centrifugal force on this interesting behaviour. We find that, as predicted in theoretical models of discs in vertical equilibrium, the CENBOL is produced only when the centrifugal force is significant and more specifically, when λ > 1.5. Outflow rate itself is found to increase with λ as well and so is the oscillation amplitude. The cause of oscillation appears to be due to the interaction among the back flow from the centrifugal barrier, the outflowing winds and the inflow. For low angular momentum, the back flow as well as the oscillation are missing. To our knowledge, this is the first time that such an oscillating solution is found with a well-tested grid-based finite difference code, and such a solution could be yet another reason of why quasi-periodic oscillations should be observed in black hole candidates that are accreting low angular momentum transonic flows. [ABSTRACT FROM AUTHOR]

Published

2016

13. Viscosity parameter in dissipative accretion flows with mass outflow around black holes.

Author

Nagarkoti, Shreeram and Chakrabarti, Sandip K.

Subjects

*ACCRETION (Astrophysics), *VISCOSITY, *ENERGY dissipation, *HYDRODYNAMICS, *BLACK holes, *COMPUTER simulation

Abstract

Numerical hydrodynamic simulation of inviscid and viscous flows have shown that significant outflows could be produced from the CENtrifugal pressure-supported BOundary Layer or CENBOL of an advective disc. However, this barrier is weakened in presence of viscosity, more so, if there are explicit energy dissipations at the boundary layer itself. We study effects of viscosity and energy dissipation theoretically on the outflow rate and show that, as the viscosity or energy dissipation (or both) rises, the prospect of formation of outflows is greatly reduced, thereby verifying results obtained through observations and numerical simulations. Indeed, we find that in a dissipative viscous flow, shocks in presence of outflows can be produced only if the Shakura-Sunyaev viscosity parameter α is less than 0.2. This is a direct consequence of modification of the Rankine-Hugoniot relation across the shock in a viscous flow, when the energy dissipation and mass-loss in the form of outflows from the post-shock region are included. If we ignore the effects of mass-loss altogether, the standing dissipative shocks in viscous flows may occur only if α < 0.27. These limits are tighter than the absolute limit of α = 0.3 valid for a situation when the shock itself neither dissipates energy nor any outflow is formed. We compute typical viscosity parameters required to understand spectral and temporal properties of several black hole candidates such as GX399-4, MAXI J1659-152 and MAXI J1836-194 and find that required α are indeed well within our prescribed limit. [ABSTRACT FROM AUTHOR]

Published

2016

14. Estimation of the mass of the black hole candidate MAXI J1659-152 using TCAF and POS models.

Author

Molla, Aslam Ali, Debnath, Dipak, Chakrabarti, Sandip K., Mondal, S., and Jana, A.

Subjects

BLACK holes, X-ray astronomy, ASTRONOMICAL observations, ACCRETION (Astrophysics), ASTROPHYSICS

Abstract

The Galactic transient black hole candidate (BHC) MAXI J1659-152 exhibited temporal and spectral evolution during its very first X-ray outburst (2010) after its discovery on 2010 September 25. Our recent studies of a few transient BHCs, including MAXI J1659-152, using the Chakrabarti-Titarchuk two-component advective flow (TCAF) solution as an additive table local model in the XSPEC software revealed details of the accretion-flow dynamics around the black holes. The TCAF model-fitted normalization (N) comes out to be almost constant throughout the entire outburst, consisting of several spectral states. We introduce two independent methods to determine the mass (MBH) of the BHC: namely (i) keeping the TCAF fitted normalization parameter in a narrow range and (ii) studying the evolution of the quasi-periodic oscillation frequency (νQPO) with time, fitting with the propagating oscillatory shock (POS) model. The predicted mass ranges of the source with these two methods are 4.7-7.8Mʘ and 5.1-7.4Mʘ, respectively. Combining the results of these two methods, we obtain a most probable mass range of the source of 4.7-7.8Mʘ or 6+1.8-1.3Mʘ. [ABSTRACT FROM AUTHOR]

Published

2016

15. PROPERTIES OF THE PROPAGATING OSCILLATORY SHOCK WAVE IN THE ACCRETION FLOWS AROUND FEW TRANSIENT BLACK HOLE CANDIDATES DURING THEIR OUTBURSTS.

Author

DEBNATH, DIPAK and CHAKRABARTI, SANDIP. K.

Subjects

*SHOCK waves, *BLACK holes, *ACCRETION disks, *STELLAR evolution, *STELLAR oscillations

Published

2015

16. Resonance condition and low-frequency quasi-periodic oscillations of the outbursting source H1743-322.

Author

Chakrabarti, Sandip K., Mondal, Santanu, and Debnath, Dipak

Subjects

*STELLAR oscillations, *ACCRETION disks, *STELLAR radiation, *STELLAR dynamics, *BLACK holes, *X-ray binaries

Abstract

It has long been proposed that low-frequency quasi-periodic oscillations (QPOs) in stellar-mass black holes or their equivalents in supermassive black holes are the result of resonances between infall and cooling timescales. We explicitly compute these two timescales in a generic situation to show that resonances are easily achieved. During an outburst of a transient black hole candidate, the accretion rate of the Keplerian disc as well as the geometry of the Comptonizing cloud change very rapidly. During some period, a resonance condition between the cooling timescale (predominantly by Comptonization) and the infall timescale of the Comptonizing cloud is roughly satisfied. This leads to low-frequency quasi-periodic oscillations (LFQPOs) of the Compton cloud and the consequent oscillation of hard X-rays. In this paper, we explicitly follow black hole candidate H1743-322 during its 2010 outburst. We compute the Compton cooling time and infall time over several days and show that QPOs take place when these two roughly agree within ~50 percent, i.e., the resonance condition is generally satisfied. We also confirm that for the sharper LFQPOs (i.e. higher Q-factors) the ratio of the two timescales is very close to 1. [ABSTRACT FROM AUTHOR]

Published

2015

17. MONTE-CARLO SIMULATIONS OF COMPTONIZATION PROCESS IN A TWO COMPONENT ACCRETION FLOW AROUND A BLACK HOLE IN PRESENCE OF AN OUTFLOW.

Author

GHOSH, HIMADRI, GARAIN, SUDIP K., GIRI, KINSUK, and CHAKRABARTI, SANDIP K.

Subjects

MONTE Carlo method, BLACK holes, ASTROPHYSICS, INTERSTELLAR medium, ELECTROMAGNETIC waves, PHOTONS

Published

2012

18. Evolution of QPOs in XTE J1550-564 in 1998 outburst: a Case of Quasi Outburst?

Author

Dutta, Broja G., Chakrabarti, Sandip K., and Pal, Partha S.

Subjects

*FLUCTUATIONS (Physics), *OSCILLATIONS, *ASTRONOMICAL perturbation, *CYCLES, *VIBRATION (Mechanics)

Abstract

It is believed that Low and Intermediate frequency Quasi-Periodic Oscillations (QPOs) may be generated due to the oscillations of the post-shock region which Comptonizes soft photons. Any movement of these perturbations is expected to change the QPO frequency systematically. Here, we report the presence of such systematic drifts both during the onset phase from the 7th of September 1998 to the 19th September 1998, when the QPO frequency was increasing monotonically from 81mHz to 13.1Hz. It started to decrease at the onset of the decline phase. On the 26th of September 1998, the QPO frequency gradually decreased to 2.62Hz and after that its value remains almost stable and no such systematic drift was observed. We therefore model the frequency drift with a propagatory oscillating shock solution. The systematic and predictable variation of the QPO frequency over a period of few weeks directly supports the view that it may due to the drifting of an oscillating shock rather than the movements of a blob inside a differentially rotating disk. [ABSTRACT FROM AUTHOR]

Published

2008

19. Standing accretion shock waves around rotating black holes in presence of cooling.

Author

Das, Santabrata and Chakrabarti, Sandip K.

Subjects

*SHOCK waves, *ACCRETION (Astrophysics), *SUPERMASSIVE black holes, *SYNCHROTRONS, *COOLING, *OSCILLATIONS

Abstract

We investigate the properties of the shock waves for a rotating accretion flow around a spinning black hole (BH) in presence of synchrotron cooling. We present all possible accretion solutions. We show that global accretion shock solutions exist for a wide range of flow parameters. We separate the region of the parameter space for steady and oscillating shocks which gradually shrinks as cooling is increased. We also find that shock fronts move closer to the BH for enhanced cooling efficiency which could be the source of high frequency quasi-periodic oscillations around the rotating black holes at higher accretion rate. [ABSTRACT FROM AUTHOR]

Published

2008

20. Evolution of the temporal and the spectral properties in 2010 and 2011 outbursts of H 1743-322.

Author

Debnath, Dipak, Chakrabarti, Sandip K., and Nandi, Anuj

Subjects

*SPECTRUM analysis, *X-ray binaries, *BLACKBODY radiation, *FLUID flow, *DATA analysis, *DYNAMICAL systems

Abstract

Abstract: The Galactic black hole candidate H 1743-322 exhibited two X-ray outbursts in rapid succession: one in August 2010 and the other in April 2011. We analyze archival data of this object from the PCA instrument on board RXTE (2–25keV energy band) to study the evolution of its temporal and spectral characteristics during both the outbursts, and hence to understand the behavioral change of the accretion flow dynamics associated with the evolution of the various X-ray features. We study the evolution of QPO frequencies during the rising and the declining phases of both the outbursts. We successfully fit the variation of QPO frequency using the Propagating Oscillatory Shock (POS) model in each of the outbursts and obtain the accretion flow parameters such as the instantaneous shock locations, the shock velocity and the shock strength. Based on the degree of importance of the thermal (disk black body) and the non-thermal (power-law) components of the spectral fit and properties of the QPO (if present), the entire profiles of the 2010 and 2011 outbursts are subdivided into four different spectral states: hard, hard-intermediate, soft-intermediate and soft. We attempt to explain the nature of the outburst profile (i.e., hardness-intensity diagram) with two different types of mass accretion flow. [Copyright &y& Elsevier]

Published

2013

21. NUMERICAL SIMULATIONS OF A TWO COMPONENT ADVECTIVE FLOW FOR THE STUDY OF THE SPECTRAL AND TIMING PROPERTIES OF BLACK HOLES.

Author

GIRI, KINSUK and CHAKRABARTI, SANDIP K.

Subjects

*BLACK holes, *ADVECTION, *VISCOSITY, *ACCRETION disks, *SHOCK waves, *COMPUTER simulation

Published

2015

22. EFFECTS OF COMPTON COOLING ON OUTFLOWS IN A TWO COMPONENT ACCRETION FLOW AROUND A BLACK HOLE: RESULTS OF A COUPLED MONTE CARLO-TVD SIMULATION.

Author

GARAIN, SUDIP K., GHOSH, HIMADRI, and CHAKRABARTI, SANDIP K.

Subjects

ACCRETION (Astrophysics), COMPTON effect, BIPOLAR outflows (Astrophysics), BLACK holes, MONTE Carlo method, HYDRODYNAMICS

Published

2015

23. Spectral properties of two-component advective flows with standing shocks in the presence of Comptonization.

Author

Mondal, Santanu and Chakrabarti, Sandip K.

Subjects

*SELF-consistent field theory, *ACCRETION disks, *HYDRODYNAMICS, *RADIATIVE transfer, *ACCRETION (Astrophysics), *BLACK holes

Abstract

We study self-consistently the hydrodynamic and spectral properties of a general class of steady-state accretion discs where we couple both the hydrodynamics and the radiative transfer. We consider a two-component accretion flow in which the Keplerian disc is immersed inside an accreting low angular momentum flow (halo) around a black hole. The injected soft photons from the Keplerian disc are reprocessed by the electrons in the halo. We study the transonic properties of such a Comptonized flow. We use the Rankine–Hugoniot relation to obtain the shock locations in the disc and compute the radiated spectrum from this shocked disc. We identify the boundary of the parameter space spanned by the specific energy and angular momentum which allows the formation of the standing shocks. We show how the boundary changes in the presence of Compton cooling. Due to the radiative loss, some energy is removed from the accreting matter and the shock moves towards the black hole to maintain the pressure balance condition. We solve the two-temperature equations with Coulomb energy exchange between the protons and the electrons, and the radiative processes such as the bremsstrahlung and thermal Comptonization. We study the variation of the hydrodynamical and spectral properties as a function of the accretion rates of the Keplerian and sub-Keplerian components. Ours is the most accurate transonic solution of an inviscid flow around a black hole to date. [ABSTRACT FROM AUTHOR]

Published

2013

24. MODEL DEPENDENCE OF OUTFLOW RATES FROM AN ACCRETION DISK IN PRESENCE OF A DISSIPATIVE STANDING SHOCK.

Author

SINGH, CHANDRA B. and CHAKRABARTI, SANDIP K.

Subjects

*ACCRETION (Astrophysics), *MATHEMATICAL models, *DEPENDENCE (Statistics), *DISKS (Astrophysics), *ENERGY dissipation, *BLACK holes, *SHOCK waves, *BIPOLAR outflows (Astrophysics)

Abstract

Solutions of black hole accretion flows with axisymmetric shocks are obtained self-consistently when the dissipation at the post-shock flow is taken into account. The Rankine-Hugoniot relationships had to be modified suitably to incorporate the energy loss as well as possible matter loss due to outflows in the post-shock region. The outflow rate from the post-shock region is also computed self-consistently. This was done by considering the quantities in the subsonic post-shock flow as the initial condition for the conical outflow. We have several major results: we find the analytical expression of the ratio of the outflow rate and the inflow rate Rṁ. We find that Rṁ strongly depends on the model assumptions which govern the flow geometry. It appears that, (a) the outflow rate is at most a few percent of the inflow rate, (b) the outflow is absent when the shock is relatively weak, (c) the outflow rate decreases with the increase in the energy loss at the post-shock region. These conclusions are very important as they have direct bearings on the observational effects. Since spectrally soft states are generally believed to be caused by the dominance of the soft photons and almost total loss of thermal energy of the Compton cloud by inverse Comptonization, a spectrally softer state should have less outflows. The opposite is generally true: A spectrally harder state will have a stronger outflow, but the result depends on the compression ratio and the adopted model. The other major result is that the model independence of the transonic properties of the flow does not hold in presence of the loss of the energy (radiation) and mass (outflow). [ABSTRACT FROM AUTHOR]

Published

2011

25. FUNDAMENTAL CONCEPTS IN TRANSONIC FLOW PARADIGM OF BLACK HOLE ASTROPHYSICS.

Author

CHAKRABARTI, SANDIP K.

Subjects

*BLACK holes, *ASTROPHYSICS, *ACCRETION (Astrophysics), *TELESCOPES, *ASTRONOMICAL observations, *COMPUTER simulation, *SHOCK waves

Abstract

Exactly three decades ago, it was realized that an accretion flow onto a black hole should be transonic. Since then, the subject has matured considerably and several new and well established concepts and methodologies have replaced earlier ways of studying accretion and winds. Not surprisingly, with the advent of the faster computers as well as better space-based telescopes, the results of numerical simulations and the observations have also improved along with the theory. Today, it is more than satisfying that the results of theory and numerical simulations, even in the context of nonmagnetic flows, agree in details of the observations exceedingly well. I present here several new concepts and intricacies which one has to get familiar with when one talks about the behavior of the transonic flows, either in accretion or in the outflows. [ABSTRACT FROM AUTHOR]

Published

2011

26. EFFECTS OF THE COMPOSITION ON TRANSONIC PROPERTIES OF ACCRETION FLOWS AROUND BLACK HOLES.

Author

CHATTOPADHYAY, INDRANIL and CHAKRABARTI, SANDIP K.

Subjects

*ACCRETION (Astrophysics), *BLACK holes, *SHOCK waves, *ANGULAR momentum (Nuclear physics), *RELATIVISTIC astrophysics, *EQUATIONS of state, *DISKS (Astrophysics), *HYDRODYNAMICS

Abstract

We study the properties of a steady, multi-species, low angular momentum accretion flow around a Schwarzschild black hole. Each species is described by a relativistic equation of state. We find that the transonic properties depend strongly on the composition of the flow. We find that an electron-positron pair plasma is the least relativistic one. This flow produces only one sonic point very close to the event horizon and does not show multiple critical points for any angular momentum or energy. When the baryons are present, the number of critical points depend on the specific energy content. Since the number of critical points decide whether the flow will have nonlinearities or shock waves, our results imply that whether standing shocks will form or not depends on the flow composition. Thus, for instance, a pure electron-positron pair plasma will never undergo a shock transition, while mixing it with some baryons (common in outflows and jets, for example) as in a completely ionized gas, will have shocks. We study in detail how the baryon loading affects the shock properties and discuss the implications in astrophysical observations. [ABSTRACT FROM AUTHOR]

Published

2011

27. Evidence for two-component flows around the black hole candidate XTE J1550−564 from spectral features during its 1998–1999 outburst.

Author

Dutta, Broja G. and Chakrabarti, Sandip K.

Subjects

*NUCLEAR counters, *SUPERMASSIVE black holes, *GRAVITATIONAL collapse, *STARS, *GALAXIES, *MILKY Way, *MAGELLANIC clouds, *GALACTIC nuclei, *ASTRONOMY

Abstract

We study the spectral properties of the accretion disc in the Galactic black hole candidate XTE J 564 during the 1998–1999 outburst when the source exhibited double-peaked eruptions. This outburst lasted for 250 d and the 2.5–25.0 keV spectral state varied smoothly from one to another several times. We show that the spectral features of the 1998–1999 outburst could be clearly understood by a two-component (Keplerian and sub-Keplerian) advective flow (TCAF). We concentrate on the spectral data from a Proportional Counter Array instrument on the RXTE satellite for the black hole XTE J 564 and fit them quite satisfactorily using TCAF model. From the spectral fit we calculate the disc parameters, such as the Keplerian rate, the sub-Keplerian rate (halo rate), the shock location and the inner edge of the Keplerian disc. This observation points to the presence of two independent components in the accretion flow and that the accretion rate at all radii need not be constant in an evolving disc. [ABSTRACT FROM AUTHOR]

Published

2010

28. MONTE CARLO SIMULATIONS OF THE THERMAL COMPTONIZATION PROCESS IN A TWO-COMPONENT ACCRETION FLOW AROUND A BLACK HOLE IN THE PRESENCE OF AN OUTFLOW.

Author

GHOSH, HIMADRI, GARAIN, SUDIP K., CHAKRABARTI, SANDIP K., and LAURENT, PHILIPPE

Subjects

MONTE Carlo method, ESTIMATION theory, EINSTEIN-Podolsky-Rosen experiment, CENTRIFUGAL force, ROTATIONAL motion

Abstract

A black hole accretion may have both the Keplerian and the sub-Keplerian component. In the so-called Chakrabarti–Titarchuk scenario, the Keplerian component supplies low-energy (soft) photons while the sub-Keplerian component supplies hot electrons which exchange their energy with the soft photons through Comptonization or inverse Comptonization processes. In the sub-Keplerian component, a shock is generally produced due to the centrifugal force. The postshock region is known as the CENtrifugal pressure–supported BOundary Layer (CENBOL). In this paper, we compute the effects of the thermal and the bulk motion Comptonization on the soft photons emitted from a Keplerian disk by the CENBOL, the preshock sub-Keplerian disk and the outflowing jet. We study the emerging spectrum when the converging inflow and the diverging outflow (generated from the CENBOL) are simultaneously present. From the strength of the shock, we calculate the percentage of matter being carried away by the outflow and determine how the emerging spectrum depends on the outflow rate. The preshock sub-Keplerian flow is also found to Comptonize the soft photons significantly. The interplay between the up-scattering and down-scattering effects determines the effective shape of the emerging spectrum. By simulating several cases with various inflow parameters, we conclude that whether the preshock flow, or the postshock CENBOL or the emerging jet is dominant in shaping the emerging spectrum depends strongly on the geometry of the flow and the strength of the shock in the sub-Keplerian flow. [ABSTRACT FROM AUTHOR]

Published

2010

29. Hydrodynamic simulations of oscillating shock waves in a sub-Keplerian accretion flow around black holes.

Author

Giri, Kinsuk, Chakrabarti, Sandip K., Samanta, Madan M., and Ryu, D.

Subjects

*HYDRODYNAMICS, *SIMULATION methods & models, *SHOCK waves, *SUPERMASSIVE black holes, *HARMONIC oscillators

Abstract

We study the accretion processes on a black hole by a numerical simulation. We use a grid-based finite difference code for this purpose. We scan the parameter space spanned by the specific energy and the angular momentum and compare the time-dependent solutions with those obtained from theoretical considerations. We found several important results. (a) The time-dependent flow behaves close to a constant height model flow in the pre-shock region and a flow with vertical equilibrium in the post-shock region. (c) The infall time-scale in the post-shock region is several times higher than the free-fall time-scale. (b) There are two discontinuities in the flow, one being just outside of the inner sonic point. Turbulence plays a major role in determining the locations of these discontinuities. (d) The two discontinuities oscillate with two different frequencies and behave as a coupled harmonic oscillator. A Fourier analysis of the variation of the outer shock location indicates higher power at the lower frequency and lower power at the higher frequency. The opposite is true when the analysis of the inner shock is made. These behaviours will have implications in the spectral and timing properties of black hole candidates. [ABSTRACT FROM AUTHOR]

Published

2010

30. Studies of dissipative standing shock waves around black holes.

Author

Das, Santabrata, Chakrabarti, Sandip K., and Mondal, Soumen

Subjects

*SUPERMASSIVE black holes, *GRAVITATIONAL collapse, *ANGULAR momentum (Nuclear physics), *ENERGY dissipation, *ASTRONOMY

Abstract

We investigate the dynamical structure of advective accretion flow around stationary as well as rotating black holes. For a suitable choice of input parameters, such as accretion rate and angular momentum (λ), a global accretion solution may include a shock wave. The post-shock flow is located at a few tens times the Schwarzchild radius and is generally very hot and dense. This successfully mimics the so-called Compton cloud, which is believed to be responsible for emitting hard radiation. Owing to the radiative loss, significant energy is removed from the accreting matter and the shock moves forward towards the black hole in order to maintain the pressure balance across it. We identify the effective area of parameter space that allows accretion flows to have some energy dissipation at the shock . As the dissipation is increased, the parameter space is reduced and finally disappears when the dissipation reaches a critical value. The dissipation has a profound effect on the dynamics of post-shock flow. By moving forward, an unstable shock, the oscillation of which causes quasi-periodic oscillations (QPOs) in the emitted radiation, will produce oscillations of high frequency. Such an evolution of QPOs has been observed in several black hole candidates during their outbursts. [ABSTRACT FROM AUTHOR]

Published

2010

31. MONTE CARLO SIMULATIONS OF THE THERMAL COMPTONIZATION PROCESS IN A TWO-COMPONENT ACCRETION FLOW AROUND A BLACK HOLE.

Author

GHOSH, HIMADRI, CHAKRABARTI, SANDIP K., and LAURENT, PHILIPPE

Subjects

*MONTE Carlo method, *ACCRETION (Astrophysics), *SUPERMASSIVE black holes, *PHOTONS, *PARTICLES (Nuclear physics)

Abstract

We compute the effects of thermal Comptonization of soft photons emitted from a Keplerian disk around a black hole by the postshock region of a sub-Keplerian flow, known as the CENtrifugal-pressure-dominated BOundary Layer (CENBOL). We show that the spectral state transitions of black hole candidates could be explained either by varying the outer boundary of the CENBOL, which also happens to be the inner edge of the Keplerian disk, or by changing the central density of the CENBOL, which is governed by the rate of the sub-Keplerian flow. We confirm the conclusions of the previous theoretical studies that the interplay between the intensity of the soft photons emitted by the Keplerian flow, the optical depth and electron temperature of the Comptonizing cloud is responsible for the state transitions in a black hole. [ABSTRACT FROM AUTHOR]

Published

2009

32. Accretion flow behaviour during the evolution of the quasi-periodic oscillation frequency of XTE J1550−564 in 1998 outburst.

Author

Chakrabarti, Sandip K., Dutta, Broja G., and Pal, P. S.

Subjects

*STELLAR evolution, *ACCRETION (Astrophysics), *OSCILLATIONS, *SHOCK waves, *SUPERMASSIVE black holes, *FLUCTUATIONS (Physics)

Abstract

Low and intermediate frequency quasi-periodic oscillations (QPOs) are thought to be due to oscillations of Comptonizing regions or hot regions embedded in Keplerian discs. Observational evidence of evolutions of QPOs would therefore be very important as they throw lights on the dynamics of the hotter region. Our aim is to find systems in which there is a well-defined correlation among the frequencies of the QPOs over a range of time so as to understand the physical picture. In this paper, we concentrate on the archival data of XTE J1550−564 obtained during 1998 outburst, and study the systematic drifts during the rising phase from the 1998 September 7 to the 1998 September 19, when the QPO frequency increased monotonically from 81 mHz to 13.1 Hz. Immediately after that, QPO frequency started to decrease and on the 1998 September 26, the QPO frequency became 2.62 Hz. After that, its value remained almost constant. This frequency drift can be modelled satisfactorily with a propagatory oscillating shock solution where the post-shock region behaves as the Comptonized region. Comparing with the nature of a more recent 2005 outburst of another black hole candidate GRO 1655−40, where QPOs disappeared at the end of the rising phase, we conjecture that this so-called ‘outburst’ may not be a full-fledged outburst. [ABSTRACT FROM AUTHOR]

Published

2009

33. Dissipative accretion flows around a rotating black hole.

Author

Das, Santabrata and Chakrabarti, Sandip K.

Subjects

*SUPERMASSIVE black holes, *COOLING, *ASTRONOMY, *GRAVITATIONAL collapse, *ACCRETION (Astrophysics)

Abstract

We study the dynamical structure of a cooling dominated rotating accretion flow around a spinning black hole. We show that non-linear phenomena such as shock waves can be studied in terms of only three flow parameters, namely the specific energy , the specific angular momentum (λ) and the accretion rate of the flow. We present all possible accretion solutions. We find that a significant region of the parameter space in the plane allows global accretion shock solutions. The effective area of the parameter space for which the Rankine–Hugoniot shocks are possible is maximum when the flow is dissipation-free. It decreases with the increase of cooling effects and finally disappears when the cooling is high enough. We show that shock forms further away when the black hole is rotating compared to the solution around a Schwarzschild black hole with identical flow parameters at a large distance. However, in a normalized sense, the flow parameters for which the shocks form around the rotating black holes are produced shocks closer to the black hole. The location of the shock is also dictated by the cooling efficiency in that higher the accretion rate , the closer is the shock location. We believe that some of the high-frequency quasi-periodic oscillations may be due to the flows with higher accretion rate around the rotating black holes. [ABSTRACT FROM AUTHOR]

Published

2008

34. NON-LINEARITIES IN ACCRETION AND WINDS AROUND ROTATING BLACK HOLES USING PSEUDO-KERR GEOMETRY.

Author

MONDAL, SOUMEN and CHAKRABARTI, SANDIP K.

Subjects

*SUPERMASSIVE black holes, *ACCRETION (Astrophysics), *ANGULAR momentum (Mechanics), *NONLINEAR waves, *SHOCK waves

Abstract

Non-linearities such as shock waves are common in accretion flows around compact objects. Exact quantification of these non-linearities will help testing time-dependent numerical codes. In this paper, we study the detailed properties of these non-linear waves in a steady accretion or wind flows around a rotating black hole. We use a pseudo-Kerr geometry for this purpose. In the context of energy preserving standing shocks, we find that there are two shock locations for a given pair of conserved flow parameters, such as specific energy and angular momentum. We also show that as the Kerr parameter is increased, the shock location moves closer to the black hole. We discuss the astrophysical implications of such solutions. [ABSTRACT FROM AUTHOR]

Published

2007

35. Quasi-periodic oscillations in quasars to nano-quasars.

Author

Chakrabarti, Sandip K.

Subjects

*OSCILLATIONS, *QUASARS, *SUPERMASSIVE black holes, *ACTIVE galaxies, *SPACE telescopes, *ULTRAVIOLET radiation

Abstract

TAUVEX brings us a unique opportunity to explore the temporal variability of UV emitting objects in the sky. One of the questions that we intend to resolve with TAUVEX is whether the 'variabilities' detected in active galaxies and quasars and in radiations around massive black holes in general are just random variations of the intensities or these are intrinsic to the disk system, and possibly due to the quasi-periodic oscillations (QPOs) which are well known to be observed in smaller black holes (nano-quasars). In this article, we present a physical mechanism for the QPOs and show that this is a generic mechanism which should be manifested in all types of active compact objects, ranging from quasars to nano-quasars. We propose some tests by which we may be able to tell if these are QPOs, even without waiting for a large number of cycles to test the periodicity. We present a few examples to impress that perhaps we have already seen QPOs in some objects. Multi-wavelength observation capabilities in TAUVEX may be used to pinpoint the nature of the variable sources more accurately. [ABSTRACT FROM AUTHOR]

Published

2007

36. Parameter space study of the magnetohydrodynamic accretion flows around compact objects.

Author

Das, Santabrata and Chakrabarti, Sandip K.

Subjects

*ACCRETION (Astrophysics), *SUPERMASSIVE black holes, *SHOCK waves, *MAGNETOHYDRODYNAMICS, *AXIAL flow, *OSCILLATIONS

Abstract

We solve the magnetohydrodynamic (MHD) equations governing axisymmetric flows around compact objects and found all possible classes of solutions for non-relativistic adiabatic accretion flows. We divide the parameter space in terms of these classes. We study the possibility of the formation of the MHD shock waves and show how the strength of the shocks depends on the flow parameters. We also show regions of the parameter space where the shock conditions are not satisfied and therefore the shocks may oscillate. These solutions are astrophysically interesting as they could give rise to quasi-periodic oscillations seen in hard X-rays. [ABSTRACT FROM AUTHOR]

Published

2007

37. Studies of accretion flows around rotating black holes – II. Standing shocks in the pseudo-Kerr geometry.

Author

Mondal, Soumen and Chakrabarti, Sandip K.

Subjects

*ACCRETION (Astrophysics), *SUPERMASSIVE black holes, *SHOCK waves, *WINDS, *FLUID dynamics

Abstract

Standing, propagating or oscillating shock waves are common in accretion and winds around compact objects. We study the topology of all possible solutions using the pseudo-Kerr geometry. We present the parameter space spanned by the specific energy and angular momentum and compare it with that obtained from the full general relativity to show that the potential can work satisfactorily in fluid dynamics also, provided the polytropic index is suitably modified. We then divide the parameter space depending on the nature of the solution topology. We specifically study the nature of the standing Rankine–Hugoniot shocks. We also show that as the Kerr parameter is increased, the shock location generally moves closer to the black hole. In future, these solutions can be used as guidelines to test numerical simulations around compact objects. [ABSTRACT FROM AUTHOR]

Published

2006

38. SIGNATURES OF ACCRETION SHOCKS IN BROADBAND SPECTRUM OF ADVECTIVE FLOWS AROUND BLACK HOLES.

Author

Mandal, Samir and Chakrabarti, Sandip K.

Subjects

*CENTRIFUGAL force, *SUPERMASSIVE black holes, *GRAVITATIONAL collapse, *ASTRONOMY, *ASTROPHYSICS

Abstract

We compute the effects of the centrifugal pressure supported shock waves on the emitted spectrum from an accretion disk primarily consisting of low angular momentum matter. Electrons are very efficiently accelerated by the accretion shock and acquire power-law distribution. The accelerated particles in turn emit synchrotron radiation in the presence of a stochastic magnetic field in equipartition with the gas. Efficient cooling of the electrons by these soft photons reduces its temperature in comparison to the protons. We explore the nature of the broadband spectra by using Comptonization, bremsstrahlung and synchrotron emission. We then show that there could be two crossing points in a broadband spectrum, one near ~10 keV and the other ~300–400 keV. [ABSTRACT FROM AUTHOR]

Published

2005

39. PROPERTIES OF ACCRETION SHOCKS IN VISCOUS FLOWS WITH COOLING EFFECTS.

Author

Das, Santabrata and Chakrabarti, Sandip K.

Subjects

*ACCRETION (Astrophysics), *SHOCK waves, *VISCOUS flow, *OSCILLATIONS, *ASTROPHYSICS, *PHYSICS research

Abstract

Low angular momentum accretion flows can have standing and oscillating shock waves. We study the region of the parameter space in which multiple sonic points occur in viscous flows in presence of various cooling effects such as bremsstrahlung and Comptonization. We also quantify the parameter space in which shocks are steady or oscillating. We find that cooling induces effects opposite to heating by viscosity even in modifying the topology of the solutions, though one can never be exactly balanced by the other due to their dissimilar dependence on dynamic and thermodynamic parameters. We show that beyond a critical value of cooling, the flow ceases to contain a shock wave. [ABSTRACT FROM AUTHOR]

Published

2004

40. Properties of accretion shock waves in viscous flows around black holes.

Author

Chakrabarti, Sandip K. and Das, Santabrata

Subjects

*ACCRETION (Astrophysics), *SUPERMASSIVE black holes, *SHOCK waves, *VISCOSITY, *ANGULAR momentum (Mechanics), *OSCILLATIONS

Abstract

Accretion flows having low angular momentum and low viscosity can have standing shock waves. These shocks arise because of the presence of multiple sonic points in the flow. We study the region of the parameter space in which multiple sonic points occur in viscous flows in the absence of cooling. We also separate the parameter space into regions allowing steady shocks and oscillating shocks. We quantify the nature of two critical viscosities which separate the flow topologies. The post-shock region being hotter, it emits harder X-rays and oscillating shocks cause oscillating X-ray intensities giving rise to quasi-periodic oscillations. We show that with the increase in viscosity parameter, the shock always moves closer to the black hole. This implies an enhancement of the quasi-periodic oscillation frequency as viscosity is increased. [ABSTRACT FROM AUTHOR]

Published

2004

41. Radiatively driven electron–positron jets from two-component accretion flows.

Author

Chattopadhyay, Indranil, Das, Santabrata, and Chakrabarti, Sandip K.

Subjects

ACCRETION (Astrophysics), SHOCK waves, ELECTRON-positron interactions, SUPERMASSIVE black holes, RADIATIVE transfer, INTERSTELLAR medium

Abstract

Matter accreting on to black holes has long been known to have standing or oscillating shock waves. The post-shock matter puffs up in the form of a torus, which intercepts soft photons from the outer Keplerian disc and inverse Comptonizes to produce hard photons. The post-shock region also produces jets. We study the interaction of both hard photons and soft photons, with on-axis electron–positron jets. We show that the radiation from post-shock torus accelerates the flow to relativistic velocities, while that from the Keplerian disc has marginal effect. We also show that the velocity at infinity or the terminal velocity ϑ depends on the shock location in the disc. [ABSTRACT FROM AUTHOR]

Published

2004

42. A COMPARATIVE STUDY OF THE TIMING AND THE SPECTRAL PROPERTIES DURING TWO RECENT OUTBURSTS (2010 AND 2011) OF H 1743-322.

Author

DEBNATH, DIPAK, CHAKRABARTI, SANDIP. K., and NANDI, ANUJ

Subjects

*STELLAR evolution, *SHOCK waves, *ACCRETION disks, *STELLAR spectra, *BLACK holes

Published

2015

43. IS COMPTON COOLING SUFFICIENT TO EXPLAIN EVOLUTION OF OBSERVED QUASI-PERIODIC OSCILLATIONS IN OUTBURST SOURCES?

Author

Mondal, Santanu, Debnath, Dipak, and Chakrabarti, Sandip K.

Subjects

ACCRETION (Astrophysics), SHOCK waves, BLACK holes, CENTRIFUGAL force, ACCRETION disks

Abstract

In outburst sources, quasi-periodic oscillation (QPO) frequency is known to evolve in a certain way: in the rising phase, it monotonically goes up until a soft intermediate state is achieved. In the propagating oscillatory shock model, oscillation of the Compton cloud is thought to cause QPOs. Thus, in order to increase QPO frequency, the Compton cloud must collapse steadily in the rising phase. In decline phases, the exact opposite should be true. We investigate cause of this evolution of the Compton cloud. The same viscosity parameter that increases the Keplerian disk rate also moves the inner edge of the Keplerian component, thereby reducing the size of the Compton cloud and reducing the cooling timescale. We show that cooling of the Compton cloud by inverse Comptonization is enough for it to collapse sufficiently so as to explain the QPO evolution. In the two-component advective flow configuration of Chakrabarti-Titarchuk, centrifugal force-induced shock represents the boundary of the Compton cloud. We take the rising phase of 2010 outburst of Galactic black hole candidate H 1743-322 and find an estimation of variation of the α parameter of the sub-Keplerian flow to be monotonically rising from 0.0001 to 0.02, well within the range suggested by magnetorotational instability. We also estimate the inward velocity of the Compton cloud to be a few meters per second, which is comparable to what is found in several earlier studies of our group by empirically fitting the shock locations with the time of observations. [ABSTRACT FROM AUTHOR]

Published

2015