Probing the extreme realm of a compact object Sudip Bhattacharyya, DAA, TIFR, Mumbai ASTROSAT website Black hole Neutron star ASTROSAT Thermonuclear burst ignited on a neutron star http://www.universetoday.com/ Courtesy: D. Page Courtesy: A. Spitkovsky Source: Space Time Travel, credit: Ute Kraus
25
Embed
Probing the extreme realm of a compact objectweb.tifr.res.in/~daim/bhattacharyya_DAA_2015.pdfof physics, such as astrophysics, nuclear physics, magneto-fluid dynamics, gravitation,
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
Probing the extreme realm of a compact object
Sudip Bhattacharyya, DAA, TIFR, Mumbai
ASTROSAT website
Black hole
Neutron star
ASTROSAT
Thermonuclear burst ignited on a neutron star
http://www.universetoday.com/
Courtesy: D. Page
Courtesy: A. Spitkovsky
Source: Space Time Travel, credit: Ute Kraus
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
Our System of Interest
Radius ~ 10 - 20 km Mass ~ 1.4 - 2.0 solar mass Core density ~ 5 -10 times the nuclear density
Neutron star vs. a city (courtesy: M.C. Miller) A cartoon of a spinning black hole (http://en.wikipedia.org/wiki/Black_hole)
A “singularity” hides behind an event horizon. No hard surface. Mass ~ 10 solar mass
Accretion disc
Neutron star or black hole
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
Our System of Interest
Radius ~ 10 - 20 km Mass ~ 1.4 - 2.0 solar mass Core density ~ 5 -10 times the nuclear density
Neutron star vs. a city (courtesy: M.C. Miller) A cartoon of a spinning black hole (http://en.wikipedia.org/wiki/Black_hole)
A “singularity” hides behind an event horizon. No hard surface. Mass ~ 10 solar mass
Low-mass X-ray binary (LMXB)
Primarily emits X-rays. But also emits in other wavelengths. Angular size is so small that cannot be spatially resolved.
Low-mass (≤ 1 solar mass) companion star
Accretion disk
Neutron star or black hole
The cosmic X-ray observing Instruments must be sent above the atmosphere (preferably by satellites). ASTROSAT, the first Indian dedicated astronomy satellite, which will simultaneously observe from optical band to hard X-rays (100 keV), will be launched in 2015.
ASTROSAT
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
The Big Questions We Ask
(1) Probing strong gravity: (a) Is the Cosmic Censorship Conjecture
(Penrose 1969) valid, or, do naked singularities exist in nature?
This is a fundamental problem of physics.
(b) Does GTR work in strong gravity
regime? Testing its predictions, such as frame-dragging. This is a fundamental problem of physics.
A measure of curvature A measure of potential
Stellar mass black holes (BH) and neutron stars (NS) give rise to the strongest gravity.
Strengths of gravity
Psaltis (2008)
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
The Big Questions We Ask
(2) Probing dense matter: What is the nature of super-dense (5-10 times the nuclear density) degenerate matter (temperature 108 K) at the neutron star core? This is a fundamental problem of physics. Particle colliders (which probe a different regime of temperature/density) cannot answer this question. One has to measure parameters (mass, radius, spin) of neutron stars to address it.
Sudip Bhattacharyya (2010)
Neutron star: surface and interior Neutron star: theoretical “mass vs. radius” curves
Courtesy: D. Page
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/ 6
The Big Questions We Ask
(3) Understanding accretion-ejection mechanism:
Motivation: (a) This is a critical astrophysical problem: accretion-ejection is common among
various kinds of objects, such as proto-stars, X-ray binaries and AGN. (b) Accretion onto black holes and neutron stars is possibly the most efficient
energy source in the universe. (c) A study of accretion-ejection in X-ray binaries provides an important tool to
probe the strong gravity regime.
What to study? The properties, size and location of various accretion and ejection components, such as, disk, jet, wind, and their dependence on source parameters, such as accretion rate. Courtesy: heasarc.gsfc.nasa.gov
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
The Big Questions We Ask
(1) Probing strong gravity
(2) Probing dense matter
(3) Understanding accretion-ejection mechanism
None of these big questions can be answered by experiments in laboratories. Accreting NSs and BHs (LMXBs) are ideal systems to address them.
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
Our Tools
Broad asymmetric iron K emission lines are observed from accreting super-massive black hole (AGN) and stellar-mass black hole (black hole LMXB) systems. They originate from the inner part of the accretion disk.
Fabian et al. (2000)
Tanaka et al. (1995)
They are a nature-given tool to measure the black hole spin and to probe the strong gravity regime.
(1) Broad relativistic spectral iron emission line from inner accretion disk
Inte
nsi
ty
Photon energy
Theoretical models of broad line for two BH spin parameter (a/M Jc/GM2) values. (Miller 2007)
Broad asymmetric iron K emission lines are observed from accreting super-massive black hole (AGN) and stellar-mass black hole (black hole LMXB) systems. They originate from the inner part of the accretion disc.
Fabian et al. (2000)
Tanaka et al. (1995)
They are a nature-given tool to measure the black hole spin and to probe the strong gravity regime.
(1) Broad relativistic spectral iron emission line from inner accretion disk
Inte
nsi
ty
Photon energy
3 = 0 implies Kerr; 3 > 0 (3 < 0) implies more prolate (oblate) than a Kerr BH.
Bambi (2012)
Our Tools
Broad asymmetric iron K emission lines are observed from accreting super-massive black hole (AGN) and stellar-mass black hole (black hole LMXB) systems. They originate from the inner part of the accretion disc.
Fabian et al. (2000)
Tanaka et al. (1995)
They are a nature-given tool to measure the black hole spin and to probe the strong gravity regime.
(1) Broad relativistic spectral iron emission line from inner accretion disk
Inte
nsi
ty
Ser X-1
Photon energy
The first relativistic iron line from a neutron star LMXB was discovered by Sudip Bhattacharyya & Strohmayer, ApJ, 664, L103 (2007). This opened up a new way to probe the strong gravity regime around neutron stars and to measure the stellar parameters.
Subsequent research discovered such lines from >10 sources, and established this new field.
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
Our Tools
(1) Broad relativistic spectral iron emission line from inner accretion disk
How to constrain neutron star equation of state (EoS) models?
Rapidly spinning neutron star structures have been calculated with full GTR effects using the formalism of Cook, Shapiro & Teukolsky.
Sudip Bhattacharyya, MNRAS, 415, 3247, (2011)
Conclusion: rinc2/GM is to be measured with better than an accuracy of 0.1 to effectively constrain EoS models.
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
Can the proposed LOFT satellite measure rinc2/GM with an accuracy of 0.1?
Rise time ≈ 0.5 - 5 seconds Decay time ≈ 10 - 100 seconds Recurrence time ≈ hours to day Energy release in 10 seconds ≈ 1039 ergs
Sun takes more than a week to release this energy.
Accumulation of accreted matter (H, He, etc.) on the neutron star surface for hours Unstable nuclear burning for seconds Thermonuclear X-ray burst.
(2) Thermonuclear X-ray Bursts
These bursts from the neutron star surface can be very useful to probe strong gravity, to measure the neutron star parameters, and to study accretion-ejection processes.
These are variations of observed intensity during thermonuclear X-ray bursts with periods very close to the neutron star spin period. They originate from asymmetric brightness patterns on the spinning neutron star surfaces.
Spinning neutron star
Our Tools (2) Thermonuclear X-ray Bursts
What are burst oscillations?
These are variations of observed intensity during thermonuclear X-ray bursts with periods very close to the neutron star spin period.
Modeling of burst oscillation light curve can be useful to measure neutron star mass and radius, which is possibly the only way to address the fundamental physics of super-dense degenerate core matter of neutron stars. Here are two examples:
NS R/M
Like
liho
od
RXTE PCA data fitting (XTE J1814-338)
1
The vertical dashed line gives the lower limit of the stellar radius-to-mass ratio with 90% confidence.
Flame spreading on a spinning neutron star (simulation)
Thermonuclear flame spreading, which happens at early phases of bursts, is a unique field, which brings together several branches of physics, such as astrophysics, nuclear physics, magneto-fluid dynamics, gravitation, etc., and hence is very useful to probe the extreme environments of neutron stars. The study of flame spreading is also important to measure neutron star parameters.
High-frequency (400-1200 Hz) quasi-periodic oscillations of X-ray intensity have been observed from many neutron star LMXBs. Their high frequencies strongly suggest that they originate within a few Schwarzschild radii of the neutron star.
High-frequency (400-1200 Hz) quasi-periodic oscillations of X-ray intensity have been observed from many neutron star LMXBs. Their high frequencies strongly suggest that they originate within a few Schwarzschild radii of the neutron star.
Upper kHz QPO Lower kHz QPO
Po
we
r
According to almost all the models, the uniquely high kHz QPO frequencies are either the accretion disk frequencies, or the combinations, beating or resonances among them, or with the neutron star spin frequency.
Therefore, kHz QPO can be a useful tool to measure neutron star parameters, to probe the strong gravity region and to test a law of gravitation. In its time, only ASTROSAT will be able to study kHz QPO, and ASTROSAT/LAXPC, with its large area in hard X-rays, and using spectro-timing methods, will advance this field significantly.
Our Tools
High-frequency (400-1200 Hz) quasi-periodic oscillations of X-ray intensity have been observed from many neutron star LMXBs. Their high frequencies strongly suggest that they originate within a few Schwarzschild radii of the neutron star.
Frequency (Hz)
Upper kHz QPO Lower kHz QPO
Po
we
r
20/01/2015 DAIM2015: Sudip Bhattacharyya
www.tifr.res.in/~sudip/
Energy (keV)
4U 1728-34 data Mukherjee & Sudip Bhattacharyya (2012)
Our Tools (4) Spectral and timing state transitions
Spectral state In
ten
sity
Fender et al. (2004)
We need to study how all features and properties (in multiwavelength: radio, IR, optical, UV, X-ray) evolve along spectral state paths to probe accretion-ejection mechanism and other scientific problems.
Research on accreting compact objects at DAA, TIFR • Next few years : ASTROSAT (will take the central role) + other X-ray missions (Chandra, XMM, NuSTAR, Astro-H, …) + observatories of other wavelengths (GMRT, optical Telescopes, etc.)
• In 2020s : (ASTROSAT + other major international observatories): ASTROSAT : should remain operational, should take a central role in DAA X-ray astronomy research, and should remain a major DAA activity (because running a science space mission requires a huge effort (e.g., Chandra, XMM-Newton, etc.)). LOFT (if approved) : Active participation in Science Working Groups (http://www.isdc.unige.ch/loft/index.php/loft-team/science-working-groups ; see White Papers in archive) + Exploring ways for an Indian participation. SKA : DAA members are actively participating in the Indian SKA science teams. TMT : DAA/TIFR members are exploring ways to join the Indian participation in TMT.
Research on accreting compact objects at DAA, TIFR • Next few years : ASTROSAT (will take the central role) + other X-ray missions (Chandra, XMM, NuSTAR, Astro-H, …) + observatories of other wavelengths (GMRT, optical Telescopes, etc.)
• In 2020s : (ASTROSAT + other major international observatories): ASTROSAT : should remain operational, should take a central role in DAA X-ray astronomy research, and should remain a major DAA activity (because running a science space mission requires a huge effort (e.g., Chandra, XMM-Newton, etc.)). LOFT (if approved) : Active participation in Science Working Groups (http://www.isdc.unige.ch/loft/index.php/loft-team/science-working-groups ; see White Papers in archive) + Exploring ways for an Indian participation. SKA : DAA members are actively participating in the Indian SKA science teams. TMT : DAA/TIFR members are exploring ways to join the Indian participation in TMT.