Presentation is loading. Please wait.

Presentation is loading. Please wait.

Understanding LMXBs in Elliptical Galaxies Vicky Kalogera.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Understanding LMXBs in Elliptical Galaxies Vicky Kalogera."— Presentation transcript:

1 Understanding LMXBs in Elliptical Galaxies Vicky Kalogera

2 Low-Mass X-Ray Binaries CXC Image Archive Accretors: NS or BH RLOF Donors: MS, RG, WD/degenerate low-mass: < 1M o Binary Periods: minutes to ~10 days Ages: old, ~ 0.1 - 10 Gyr Persistent X-rays: ~10 Myr - ~1 Gyr LMXBs form in both galactic fields (isolated binaries) globulars (dynamical interactions)

3 courtesy Sky & Telescope Feb 2003 issue How do Low-Mass X-ray binaries form in galactic fields ? primordial binary Common Envelope: orbital contraction and mass loss NS or BH formation X-ray binary at Roche Lobe overflow

4 LMXB Population Modeling Population Synthesis Calculations: necessary Basic Concept of a Statistical Description: evolution of an ensemble of binary and single stars with focus on XRB formation and their evolution through the X-ray phase (ideally in both galactic field and globulars).

5 Population Synthesis Elements Star formation conditions: > time and duration, metallicity, IMF, binary properties

6 Population Synthesis Elements Star formation conditions: > time and duration, metallicity, IMF, binary properties Modeling of single and binary evolution > mass, radius, core mass, wind mass loss > orbital evolution: e.g., tidal synchronization and circularization, mass loss, mass transfer > mass transfer modeling: stable driven by nuclear evolution or angular momentum loss thermally unstable or dynamically unstable > compact object formation: masses and supernova kicks > X-ray phase: evolution of mass-transfer rate and X-ray luminosity

7 Population Synthesis Elements Star formation conditions: > time and duration, metallicity, IMF, binary properties Modeling of single and binary evolution > mass, radius, core mass, wind mass loss > orbital evolution: e.g., tidal synchronization and circularization, mass loss, mass transfer > mass transfer modeling: stable driven by nuclear evolution or angular momentum loss thermally unstable or dynamically unstable > compact object formation: masses and supernova kicks > X-ray phase: evolution of mass-transfer rate and X-ray luminosity

8 Population Synthesis Elements Star formation conditions: > time and duration, metallicity, IMF, binary properties Modeling of single and binary evolution > mass, radius, core mass, wind mass loss > orbital evolution: e.g., tidal synchronization and circularization, mass loss, mass transfer > mass transfer modeling: stable driven by nuclear evolution or angular momentum loss thermally unstable or dynamically unstable > compact object formation: masses and supernova kicks > X-ray phase: evolution of mass-transfer rate and X-ray luminosity

9 Population Synthesis Elements Star formation conditions: > time and duration, metallicity, IMF, binary properties Modeling of single and binary evolution > mass, radius, core mass, wind mass loss > orbital evolution: e.g., tidal synchronization and circularization, mass loss, mass transfer > mass transfer modeling: stable driven by nuclear evolution or angular momentum loss thermally unstable or dynamically unstable > compact object formation: masses and supernova kicks > X-ray phase: evolution of mass-transfer rate and X-ray luminosity

10 Population Synthesis Elements Star formation conditions: > time and duration, metallicity, IMF, binary properties Modeling of single and binary evolution > mass, radius, core mass, wind mass loss > orbital evolution: e.g., tidal synchronization and circularization, mass loss, mass transfer > mass transfer modeling: stable driven by nuclear evolution or angular momentum loss thermally unstable or dynamically unstable > compact object formation: masses and supernova kicks > X-ray phase: evolution of mass-transfer rate and X-ray luminosity

11 Population Synthesis Elements Star formation conditions: > time and duration, metallicity, IMF, binary properties Modeling of single and binary evolution > mass, radius, core mass, wind mass loss > orbital evolution: e.g., tidal synchronization and circularization, mass loss, mass transfer > mass transfer modeling: stable driven by nuclear evolution or angular momentum loss thermally unstable or dynamically unstable > compact object formation: masses and supernova kicks > X-ray phase: evolution of mass-transfer rate and X-ray luminosity Our population synthesis code: StarTrack Belcynski et al. 2006 including (simple) cluster dynamics: Ivanova et al. 2005

12 XLFs in Elliptical Galaxies (3-4)x10 36 - (5-6)x10 38 erg/s XLF slope: 0.9 +- 0.1 Fabbiano et al., Kim et al. 2006

13 Field LMXB models for NGC 3379 and NGC4278 Star Formation: delta-function at t=0 Population Age: 9-10 Gyr Metallicity:Z=0.03 (1.5 x solar) Total Stellar Mass:3 x 10 10 M o Binary Fraction:50% Initial Mass Fn:power-law index -2.7 (Scalo/Kroupa) also -2.35(Salpeter) CE efficiency:50% also:100% Fragos, VK, Belczynski, et al. 2007 See poster by Fragos et al. (#155.01)

14 Field LMXB models for NGC 3379 and NGC4278 best-fit XLF slope: 0.9 NS accretors dominate over BHs Transients in outburst more numerous than Persistent sources XLF shape depends on transient Duty Cycle: L out =min (L X /DC, 2L EDD ) i.e., empty disk mass accumulated during quiescence DC ~ 15-20% favored

15 Field LMXB models for NGC 3379 and NGC 4278 NS accretors dominate over BHs Transients in outburst more numerous than Persistent sources L out =min (L X /DC, 2L EDD ) DC ~ 15-20% favored L out dependent on P orb (claimed for MW BHs) clearly inconsistent with data

16 Field LMXB models for NGC 3379 and NGC 4278 Dominant LMXB Donor Types: < ~5x10 36 erg/s transient LMXBs with MS donors 5x10 36 - 2x10 37 persistent LMXBs with RG donors > ~2x10 37 transient LMXBs with RG donors (not just transient RG as in Piro & Bildsten 2002)

17 Field LMXB models for NGC 3379 and NGC 4278 LMXBs contributing to the observed XLF: L X > 5x10 36 erg/s

18 Field LMXB models for NGC 3379 and NGC 4278 Short & old (10Gyr ago) star formation episode does NOT lead to similar LMXB formation pattern LMXB formation rate: very high at ~500Myr but continues at lower levels for 10Gyr to present Short-lived LMXBs (e.g., persistent ultra-compacts) follow the LMXB formation rate pattern and NOT the star formation of the galaxy

19 Field LMXB models for NGC 3379 and NGC 4278 Model Normalization depends on: assumed total galaxy mass (3x10 10 M o ) assumed binary fraction (50%) Total Galaxy Mass depends on: total stellar light assumed mass-to-light ratio(uncertain by ~2) NGC 3379: 1-3 x 10 10 M o (uncertain by ~3) NGC 4278: same (within 25%) total stellar light Models favored based on XLF slope naturally give normalization consistent with observations: NGC 3379: within ~3 NGC 4278: within 15%

20 LMXBs in Globular Clusters Bildsten & Deloye 2002: NS with WD donors in ultra-compact binaries ( ~10 min orbital periods) persistent, short-lived (1-10Myr), continually formed through dynamical interactions XLF slope (~ 0.8) and normalization consistent with observations (within uncertainties) up to ~5x10 38 erg/s

21 LMXBs Above the 'Break'... Ivanova & Kalogera 2006: BH transients in outburst RG or MS donors XLF slope possible tracer of BH mass spectrum... @ (4-5)x10 38 erg/s(i.e., NS Eddington limit for He) King 2002: BH transients in outburst wide orbits, RG donors Sarazin et al. 2001: LMXBs with BH accretors Bright XRBs in GCs ?? Kalogera et al. 2004: 1-2 BH LMXBs per cluster BUT low detection probability (transients)

22 LMXBs in Elliptical Galaxies Slope and Normalization of XLF in ~5x10 36 – 5x10 38 erg/s can be explained by both: Field NS-LMXBs with low-mass MS and RG donors (transient & persistent) GC ultra-compact NS-LMXBs (persistent) Current Conclusions – Open Issues Q: Points to contributions from both field and clusters, but how can different LMXB types give similar XLF slope &normalization? Bright-end XLF could be due to transient BH-LMXBs in outburst Field and GC XLFs similar, but note: small-N sample Q: Given BH evolution in GCs and transient nature, are there too many bright point sources in GCs ? Q: Could bright sources in GCs be due to superposition ? Q: Could all bright sources be simply super-Eddington NS-LMXBs (by x10!) ? Where are the BH-LMXBs, similar to transients in the Milky Way?

23 LMXBs in Elliptical Galaxies Models of Field NS-LMXBs are favored with: Transient DC ~15% Outburst Lx connected to long-term mass transfer rate and DC: empty disk mass accumulated during quiescence Moderate CE efficiencies Shape changes at ~1x1037 erg/s could be connected to outburst Lx and DC Current Conclusions – Open Issues Even in the field LXMB formation rate is sustained over long timescales after an early phase of enhanced formation

Download ppt "Understanding LMXBs in Elliptical Galaxies Vicky Kalogera."

Similar presentations

Inspiraling Compact Objects: Detection Expectations

Inspiraling Compact Objects: Detection Expectations
A New Relativistic Binary Pulsar: Gravitational Wave Detection and Neutron Star Formation Vicky Kalogera Physics & Astronomy Dept with Chunglee Kim (NU)

A New Relativistic Binary Pulsar: Gravitational Wave Detection and Neutron Star Formation Vicky Kalogera Physics & Astronomy Dept with Chunglee Kim (NU)
X-ray pulsars in wind-fed accretion systems 王 伟 (NAOC) July 2009, Pulsar Summer School Beijing.

X-ray pulsars in wind-fed accretion systems 王 伟 (NAOC) July 2009, Pulsar Summer School Beijing.
Formation of Globular Clusters in  CDM Cosmology Oleg Gnedin (University of Michigan)

Formation of Globular Clusters in  CDM Cosmology Oleg Gnedin (University of Michigan)
Christian Knigge University of Southampton School of Physics & Astronoy Disk Stability vs Close Binary Evolution Rob Hynes (LSU) Christian Knigge University.

Christian Knigge University of Southampton School of Physics & Astronoy Disk Stability vs Close Binary Evolution Rob Hynes (LSU) Christian Knigge University.
Accretion Processes in GRBs Andrew King Theoretical Astrophysics Group, University of Leicester, UK Venice 2006.

Accretion Processes in GRBs Andrew King Theoretical Astrophysics Group, University of Leicester, UK Venice 2006.
Accretion in Binaries Two paths for accretion –Roche-lobe overflow –Wind-fed accretion Classes of X-ray binaries –Low-mass (BH and NS) –High-mass (BH and.

Accretion in Binaries Two paths for accretion –Roche-lobe overflow –Wind-fed accretion Classes of X-ray binaries –Low-mass (BH and NS) –High-mass (BH and.
Getting to Eddington and beyond in AGN and binaries! Chris Done University of Durham.

Getting to Eddington and beyond in AGN and binaries! Chris Done University of Durham.
On the Roche Lobe Overflow Reporter: Wang Chen 12/02/2014 Reference: N. Ivanova, 1406.3475v1.

On the Roche Lobe Overflow Reporter: Wang Chen 12/02/2014 Reference: N. Ivanova, v1.
Vicky Kalogera Jeremy Sepinsky with Krzysztof Belczynski X-Ray Binaries and and Super-Star Clusters Super-Star Clusters.

Vicky Kalogera Jeremy Sepinsky with Krzysztof Belczynski X-Ray Binaries and and Super-Star Clusters Super-Star Clusters.
Magnetars origin and progenitors with enhanced rotation S.B. Popov, M.E. Prokhorov (Sternberg Astronomical Institute) (astro-ph/0505406)

Magnetars origin and progenitors with enhanced rotation S.B. Popov, M.E. Prokhorov (Sternberg Astronomical Institute) (astro-ph/ )
Mass Loss and Evolution of Low-Mass X-ray Binaries Xiang-Dong Li Department of Astronomy Nanjing University 2009-5-20.

Mass Loss and Evolution of Low-Mass X-ray Binaries Xiang-Dong Li Department of Astronomy Nanjing University
Using Observables in LMXBs to Constrain the Nature of Pulsar Dong, Zhe & Xu, Ren-Xin Peking University Sep. 16 th 2006.

Using Observables in LMXBs to Constrain the Nature of Pulsar Dong, Zhe & Xu, Ren-Xin Peking University Sep. 16 th 2006.
X-ray Binaries in Nearby Galaxies Vicky Kalogera Northwestern University with Chris Belczynski (NU) Andreas Zezas and Pepi Fabbiano (CfA)

X-ray Binaries in Nearby Galaxies Vicky Kalogera Northwestern University with Chris Belczynski (NU) Andreas Zezas and Pepi Fabbiano (CfA)
Black Hole Formation and Kicks Vicky Kalogera Physics & Astronomy Dept with Bart Willems Mike Henninger Todd Levin Natasha Ivanova and Chris Fryer (LANL)

Black Hole Formation and Kicks Vicky Kalogera Physics & Astronomy Dept with Bart Willems Mike Henninger Todd Levin Natasha Ivanova and Chris Fryer (LANL)
1 Magnetars origin and progenitors with enhanced rotation S.B. Popov, M.E. Prokhorov (Sternberg Astronomical Institute) (astro-ph/0505406) Poster N 21.

1 Magnetars origin and progenitors with enhanced rotation S.B. Popov, M.E. Prokhorov (Sternberg Astronomical Institute) (astro-ph/ ) Poster N 21.
The Transient Universe: AY 250 Spring 2007 Existing Transient Surveys: High Energy II: X-ray Binaries Geoff Bower.

The Transient Universe: AY 250 Spring 2007 Existing Transient Surveys: High Energy II: X-ray Binaries Geoff Bower.
X-ray binaries. Rocket experiments. Sco X-1 Giacconi, Gursky, Hendel 1962.

X-ray binaries. Rocket experiments. Sco X-1 Giacconi, Gursky, Hendel 1962.
X-ray sources in early-type galaxies Tom Maccarone (University of Southampton)

X-ray sources in early-type galaxies Tom Maccarone (University of Southampton)
Two stories from the life of binaries: getting bigger and making magnetars Sergei Popov, Mikhail Prokhorov (SAI MSU) This week SAI celebrates its 175 anniversary.

Two stories from the life of binaries: getting bigger and making magnetars Sergei Popov, Mikhail Prokhorov (SAI MSU) This week SAI celebrates its 175 anniversary.

Similar presentations

Ads by Google