860 likes | 1.08k Views
The diversity of High-Mass X-ray binaries. Agios Nikolaos October 2010. Ignacio Negueruela. where astrologers roam …. High-mass X-ray binaries. High-mass X-ray binaries are systems containing a compact object accreting from a massive star. Good separation from LMXBs.
E N D
The diversity of High-Mass X-ray binaries Agios Nikolaos October 2010 Ignacio Negueruela where astrologers roam …
High-mass X-ray binaries • High-mass X-ray binaries are systems containing a compact object accreting from a massive star. • Good separation from LMXBs. • Very few intermediate-mass objects: LMC X-3, V4641 Sgr • Fundamental tools for astrophysics, cf. Cen X-3 & Cyg X-1. • Massive star is the main (only) contributor to optical and infrared brightness.
X-ray pulsars • Most massive X-ray binaries are X-ray pulsars magnetised neutron stars • We know of two black hole systems, one in the Milky Way (Cyg X-1; O9.7Iab), and one in the LMC (LMC X-1, O8III-V) . • Others are being found in nearby galaxies: M33 X-7 and IC 10 X-1 (talks by Fabbiano, Pietsch) • Weird cases: Cyg X-3, SS433; HMXBs? Related to ULXs? (talk by Roberts) • Presence of strong magnetic field somehow inhibits jet formation no radio detections. • Nature of donor determines main properties.
X-ray spectra of accreting pulsars • The X-ray spectra of accreting pulsars are generally fitted to phenomenological models (power-law+cutoff) • Increasing effort to interpret them in physical terms. Bulk Comptonisation of thermal components (e.g., Becker & Wolff 2007, ApJ 654, 435) Talk by Haberl
X-ray pulsars Be star Supergiant Modern version of Corbet’s diagram (Corbet 1986, MNRAS 220, 1047)
Classes of HMXBs Be/X-ray binaries Accretion from the wind of a supergiant Roche-lobe overflow
Classical HMXB Cen X-3 SMC X-1 + LMC X-1 (BH) LMC X-4
Classical HMXBs • Short orbital periods (2-3 days) • Circularised orbits • Incipient Roche-lobe overflow • The stars may be bloated, and are over-luminous for their mass • Formation of an accretion disk results in high LX detectable in other galaxies Van der Meer et al. (2007, A&A 473, 523)
Classical HMXBIncipient Roche-lobe overflow LX 1038 erg s-1
Formation channel for HMXBs • Case C mass transfer • q << 1 • Non-conservative evolution via common envelope • Results in SG+BH • Only way to make a BH in a binary? (talk by Casares) Wellstein & Langer (1999; A&A 350, 148)
Note: many more Be/X in the SMC Talk by Coe Be/X-ray binaries
Be/X-ray binaries a Be star isan early type (O7 to A1) star, not very evolved (luminosity class III-V), which shows - or has shown - emission in the H line (see Porter & Rivinius 2003, PASP 115, 1153 for a review). • Other Balmer and singly-ionised metallic lines (Fe II, Cr II, etc) also seen in emission. HeI in emission in stars earlier than B2. At sufficient resolution, all lines are double peaked. • There is also an infrared excess due to continuum emission.
Be/X-ray binaries • These characteristics can be explained by the presence of a disk of material expelled from the star. • Currently the model favoured is the decretion viscous disk (Lee et al. 1991, MNRAS 250, 432), which can reproduce most observational characteristics (Porter 1999, A&A 348, 512; Okazaki 2001, PASJ 53, 119) • At a given time, around 10% of early-B stars are in a Be star phase • But the Be phenomenon is very variable. Stars move from Be to non–Be phase.
Therefore … A Be/X-ray binary is made of • A Be star – observationally always O9-B1 both in the Galaxy and the LMC • A compact object accreting material from the disk of the Be star – observationally always a neutron star ►X-ray pulses detected whenever one looks hard enough. Indistinguishable distribution in the SMC (McBride et al. 2008; MNRAS 388, 1198)
X-ray lightcurves Persistent sources • Relatively low LX ( 1034 erg s-1). • Small intensity fluctuations (factor 10) without an obvious temporal pattern. Transients • Quiescence: low (≤1035 erg s-1) or non-detectable LX. • Series of outbursts with relatively high X-ray luminosity (Lx 1037 erg s-1), separated by the (suspected) orbital period (Type I or normal according to Stella et al. 1986, ApJ 308, 669). • Larger outbursts with Lx> 1037 erg s-1 (Lx ≈ LEdd ), lasting several weeks and not showing modulation with the orbital period (giant or Type II) .
X-ray lightcurve of the persistent Be/X-ray binary X Per (4U 0352+30), taken with the All Sky Monitor on board RossiXTE Porb = 250.0 d, Pspin = 837.6 s, e = 0.11
X-ray lightcurves Persistent sources • Relatively low LX ( 1034 erg s-1). • Small intensity fluctuations (factor 10) without an obvious temporal pattern. Transients • Quiescence: low (≤1035 erg s-1) or non-detectable LX. • Series of outbursts with relatively high X-ray luminosity (Lx 1037 erg s-1), separated by the (suspected) orbital period (Type I or normal according to Stella et al. 1986, ApJ 308, 669). • Larger outbursts with Lx> 1037 erg s-1 (Lx ≈ LEdd ), lasting several weeks and not showing modulation with the orbital period (giant or Type II) .
X-ray lightcurve of the prototype Be/X-ray transient EXO 2030+375, taken with the All Sky Monitor on board RossiXTE Porb = 46.0 d, Pspin = 41.7s, e = 0.41
X-ray lightcurve of the Be/X-ray transient MXB 0656 -072, taken with the All Sky Monitor on board RossiXTE. The only previous recorded outburst took place in 1974 (but there was another one four years later). Porb = ? d, Pspin = 160.7s
Several transients display series of Type I outbursts after (and only after) a giant outburst. 2S 1417-624Porb = 42.1 d, Pspin= 17.6s, e = 0.45
Optical studies • Optical monitoring reveals strong changes in the line profiles tracers of the disk’s dynamics • These changes are generally accompanied by large photometric variability • They can be explained as large variations in the disk’s configuration Reig et al. (2007, A&A 462, 1081)
The truncated disk modelOkazaki & Negueruela (2001, A&A 377, 161) • The phenomenology observed implies strong interaction between the different system components. This can be easily understood in terms of the decretion disk model. • If the disk is supported by viscosity, the neutron star exerts a torque on disk particles that makes them lose angular momentum. • As a consequence, the disk can only grow up to a certain size, and will be truncated at one of the commensurabilities between the Keplerian orbital period of the neutron star and disk particles the disk acts as reservoir of mass.
Model successes The model effectively explains two observational facts: • There is a good correlation between the orbital period and the maximum EW(H) measured (Reig et al. 1997, A&A 322, 193) the neutron star controls the size of the disk. • Analysis of emission-line shapes and infrared excess indicates rather higher densities in the disks of Be/X-ray binaries than in those of isolated Be stars (Zamanov et al. 2001, A&A 367, 884). The model predicts a strong dependence of the observed behaviour on the orbital eccentricity, which is generally observed to hold.
But there are exceptions … • The more Be/X-ray binaries we know, the more difficult it seems to find a common pattern in their behaviour. • I trust, however, that all those different behaviours arise from the very complex dynamical interplay between the components of the systems and can finally be reduced to the same physical processes. KS 1947+300 Porb= 40.4 d, Pspin= 18.7s, e = 0.03
Where do they come from? • Be/X-ray binaries are descended from moderately massive binaries that undergo a phase of mass transfer • They are believed to originate from relatively close systems with q<0.5 in which semi-conservative mass transfer is possible • Typical age ≥ 10 Myr
See Coe’s talk for SMC population Considered as a population, BeXBs can be used to set constraints on formation models and hence on basic physics. • There is growing evidence that a substantial population of Be/X-ray binaries with low eccentricity exists. • Inference of electron-capture SN dependence on previous binary history. Podsiadlowski et al. 2004, ApJ 612, 1044
The Be + WD mystery • Population synthesis models provide tools to analyse populations (e.g., Van Bever & Vanbeveren 1997, A&A 322, 116; Raguzova 2001 A&A 367, 848). • All population synthesis models that have been elaborated predict that, for every Be + neutron star binary, there should be ~ 10 Be + WD binaries. • No such system has been conclusively identified. They are very hard to pinpoint, but there should be many!
The Be + WD mystery • Population synthesis models provide tools to analyse populations (e.g., Van Bever & Vanbeveren 1997, A&A 322, 116; Raguzova 2001 A&A 367, 848). • All population synthesis models that have been elaborated predict that, for every Be + neutron star binary, there should be ~ 10 Be + WD binaries. • No such system has been conclusively identified. They are very hard to pinpoint, but there should be many! This renders the models somewhat suspect!
There’s a correlation here … Be/X-ray binaries
Equilibrium at which corotation velocity at the magnetospheric radius equals Keplerian velocity (Corbet 1986, MNRAS 220, 1047; Waters & van Kerkwijk 1989, A&A 223, 196)
Equilibrium at which corotation velocity at the magnetospheric radius equals Keplerian velocity (Corbet 1986, MNRAS 220, 1047; Waters & van Kerkwijk 1989, A&A 223, 196)
Evolved O8-B2 stars (luminosity class I)
Supergiant X-ray binaries Vela X-1: • Short term flaring • Long term variability by a factor of 4 Ribó et al. 2006 (A&A, 449, 687) Flare from 4U 1907+09Fritz et al. 2006 (A&A 458, 885)
Radiative winds from hot stars Line Scattering: Bound Electron Resonance Heavy ions have large Thompson cross sections The law 0.8 – 1.2 Review: Kudritzki & Puls 2000, ARA&A, 38, 613 Images stolen from Stan Owocki
Velocity Density Development of instability smooth wind Owocki & Rybicki 1984, ApJ, 284, 337 cf. Feldmeier et al. 1997, A&A, 322, 878 Images stolen from Stan Owocki
Wind clumping • Clumping factor • Size and geometry of clumps • Shells or blobs • Optically thin? 1D simulations Runacres & Owocki 2002, A&A, 381, 1015 2D simulations Dessart & Owocki 2003, A&A, 406, L1 Porous winds Owocki et al. 2004, ApJ, 616, 525 Oskinova et al. 2006, MNRAS, 372, 313 Constraints from spectra Prinja et al. 2005, A&A 430, L41 Bouret et al. 2005, A&A, 438, 301 Puls et al. 2006, A&A, 454, 625
Bondi-Hoyle-Lyttleton accretion Dependence of LX on eccentricity Reig et al. (2003, A&A 405, 285) See review: Edgar 2004, New Ast. Rev. 48, 843
But this also becomes unstable … Transverse instability close to stagnation point (Foglizzo et al. 2005; A&A 435, 397) Can (transient) accretion disks form? Perturbed accretion flow (Frixell & Taam 1988, ApJ 335, 862)
This is a complex problem A photo-ionization wake in Vela X-1 Kaper et al. (1994, A&A 289, 846)
This is a complex problem A photo-ionization wake in Vela X-1 Kaper et al. (1994, A&A 289, 846) A tidally induced accretion stream forms in the models of Blondin et al. (1991, ApJ 371, 684), which incorporate a realistic representation of the physics.
X-rays and winds A photo-ionization wake in Vela X-1 Kaper et al. (1994, A&A 289, 846)
There is feedback everywhere Tidally induced non-radial pulsations in Vela X-1 Quaintrell et al. (2003, A&A 401, 313)
Formation channel for SGXBs • Case A mass transfer • q 1 • Conservative evolution with two mass-transfer phases • Results in SG+NS Wellstein & Langer (1999; A&A 350, 148)
Supergiant Fast X-ray transients • A group of flaring sources with very short outbursts and supergiant companions. • Transient emission composed by many flares reaching LX 1036 -1037 erg s-1 • Persistent emission at lower luminosity LX 1033 -1034 erg s-1 • Deep quiescence at LX 1032 erg s-1 (Giunta et al. 2009, MNRAS 399, 744; Bozzo et al. arXiv:1004.2059; Sidoli et al. 2010 arXiv:1007.1091) e.g., Romano et al. 2010, Mem. SAI 81, 332
Parameters of SFXTs Optical counterpart to AX 1845.0-0433 (VLT+FORS1)
The real outbursts Three days of Suzaku observations of IGR J17544-2619 • Outburst (series of flares) is 1 day. • Single flare is 3 minutes • Fastest doubling time is 4 seconds. Data and graphics by courtesy of D. M. Smith
Looking for a difference • This leaves several options: • Difference in wind structure • Difference in wind geometry • Difference in accretion process
Clumpy wind • First proposed by in’t Zand (2005, A&A 441, L1) to explain behaviour of IGR J17544-2619. • All winds from OB stars are likely clumpy. • Classical supergiant X-ray binaries also show flares. INTEGRAL monitoring of Vela X-1 (Kreykenbohm et al. 2008, A&A 492, 511)
Equatorial overdensity • Model proposed by Sidoli et al. (2007, A&A 476, 1307) to explain behaviour of IGR J11215-5952. • Not clear how to extend it to other sources. • Are winds spherically symmetric?