12 Years of ChandraMay 23, 2011 X-ray Line Diagnostics of Shocked Outflows in Eta Carinae and Other...
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![Page 1: 12 Years of ChandraMay 23, 2011 X-ray Line Diagnostics of Shocked Outflows in Eta Carinae and Other Massive Stars M. F. Corcoran.](https://reader035.fdocuments.us/reader035/viewer/2022081516/56649d605503460f94a417e0/html5/thumbnails/1.jpg)
12 Years of Chandra May 23, 2011
X-ray Line Diagnostics of Shocked Outflows in Eta Carinae and Other Massive Stars
M. F. Corcoran
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12 Years of Chandra May 23, 2011
Overview
• Introduction: Problems of Mass and Mass Loss • X-ray Fine Analysis as a Probe of Mass Loss• Mass Outflows and Shocks:
a) Embedded Wind Shocks in single starsb) Colliding Wind Shocks in binaries
• Summary and More Questions
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12 Years of Chandra May 23, 2011
Introduction: The Masses of Massive stars
Mass is the fundamental stellar parameter
but as it increases it becomes (observationally) less well constrained
Moffat 1989
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12 Years of Chandra May 23, 2011
Weight Loss Secrets of the Stars
• Mass is lost due to– radiatively driven stellar winds – Transfer/Roche Lobe leaks– Eruptions– Explosions…
Meynet & Maeder 2003
Mass Loss: Crucial impact on Evolution
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12 Years of Chandra May 23, 2011
Problems Measuring Mass Loss• Smooth wind vs. clumped? (Mass-loss rates obtained from P V wind profiles are
systematically smaller than those obtained from fits to Hα emission profiles or radio free-free emission by median factors of ~20–130, Fullerton, Massa & Prinja 2006)
• spherical or not?• eruption: timescales & rates?• explosion: core & remnant amounts?
Beginning to End…
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12 Years of Chandra May 23, 2011
X-ray Studies of Mass Loss
• All observed OB stars in the range B2V–O2I are X-ray emitters• Thermal X-rays arise from at least 3 (non-exclusive) shock
processes: embedded wind shocks from unstable line driving wind-wind collisions in binaries magnetically-confined wind shocks
• X-rays sensitive to detailed mass loss process: Shocks depend on density and velocity as f(r) continuum and lines sensitive to overlying opacity
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12 Years of Chandra May 23, 2011
Some Observed X-ray Properties• For single OB stars, Lx α 10–7 Lbol (known since days of the Einstein
Observatory)• Single WR stars very weak X-ray sources
Naze et al.2011 Chandra Carina Project
O starsB stars
Broadly Speaking:• Emission thermal; kT < 1 keV for single O
stars; lots of emission lines• Single stars: X-ray emission non-variable (but
see q2 Ori A, Schulz et al. 2996, Mitschang et al. 2009)
• Binaries: may be harder (kT>2 keV); brighter; variable
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12 Years of Chandra May 23, 2011
Questions• What is the spatial distribution of the shocked gas in the
stellar wind?
• What is the temperature distribution vs. radius?
• What does the shocked gas tell us about the detailed mass loss process (mass loss rates, velocity laws, unstable regions, large-scale vs. small-scale clumps)
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12 Years of Chandra May 23, 2011
Tools: High Energy High Resolution Spectrometry
• Stellar wind velocities (1000-3000 km/s) generate distribution of X-ray emitting gas in the Chandra/XMM band (0.2-10 keV)
• Shocked gas generates thermal X-ray line emission useful for detailed measures of wind flow & densities
• High-energy lines particularly important since inner winds have high optical depth at soft X-ray energies (E<1 keV)
• HETG spectroscopy provides a unique tool:
– energy band matches wind dynamics– spectrally resolve broad lines, esp. at high energies– spatially resolve clustered stars
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12 Years of Chandra May 23, 2011
DiagnosticsProcess/Property Diagnostic Comments/Complications
wind velocity and density profile Line profile shape profiles sensitive to velocity, impact parameter, density/optical depth
ionization process (collisions vs. radiation) G=(F+I)/R (~1 collisional; >4 photoionized) resonance line scattering, optical depth effects
Equilibrium vs. Non-Eq. G > 1, R> Ro, Li-like satellites non-eq
Abundance Resonance line ratios of different elements
Uncertainty due to poorly constrained ion fractions
Location R=F/I sensitive both to ambient particle and UV radiation density; blending with satellite lines may be important
Electron Temperature G ratio, H/He ratio photoionization; resonance scattering; distinct formation regions
Non-Thermal Processes ratio of satellite to resonance lines line broadness
see Porquet, Dubau, Grosso 2011
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12 Years of Chandra May 23, 2011
a) Embedded Wind Shocks• radiative driving force which generates winds in OB and WR stars unstable
to Doppler shadowing (Lucy & White 1980, Feldmeier 1997)• Wind should break up into slow dense clumps embedded within a lower
density, fast wind• collisions produce shock heated gas dependent on local velocity field• Temperatures typically millions of K since shocks expected to occur in
wind acceleration zone close to the star• Opacity of overlying wind beyond the acceleration zone should reduce the
red-shifted portion of the line relative to the blue shifted portion, dependent on wind density
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12 Years of Chandra May 23, 2011
Zeta vs. Zeta
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12 Years of Chandra May 23, 2011
Line Profiles• Widths: narrow to broad
• in general FWHM << 2x wind velocity
• Centroids: zero to negative blueshifts • No redshifts?
• Symmetric or Asymmetric?
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12 Years of Chandra May 23, 2011
Single Star Summary
• Lines broad but only 0.2 < HWHM < 0.8 (Gudel & Naze 2009)
• EMX << EMwind
• Profiles (apparently) symmetric; centroids show small blueshifts (exc. Zeta Pup).
• Opacities low; wavelength-dependent?
• Lines apparently form rather deep in the wind (Ro~1.5-1.8 R*)
• Zeta Pup: opacity wavelength dependent, but profiles require a reduction of a factor of 3 in mass loss rate (Cohen et al. 2010)
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12 Years of Chandra May 23, 2011
b) Eta Car and WR 140: The Thermal Spectra of Colliding Winds
Long-Period, eccentric colliding wind systems are excellent laboratories for studying:– the development of astrophysical shocks– the physics of line formation– the process of mass loss in more than 2 dimensions
Key properties:location of X-ray emitting volume constrained
to the wind-wind shock boundaryIn eccentric systems, variations of density (at
constant temperature) around the orbit clumping-free mass loss rates?
Pittard 2007
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12 Years of Chandra May 23, 2011
Eta Carinae: LBV+?, P=5.5yr
1820 1850 1880 1910 1940 1970 2000
50 yrs
V-Band Lightcurve
“Great Eruption”
A. Damineli
5.5 yr
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12 Years of Chandra May 23, 2011
Eta Car: Orbital and Wind Geometry
3D SPH model (Okazaki et al. 2008)
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12 Years of Chandra May 23, 2011
Eta Car: X-ray Variations
Sampling with HETG
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12 Years of Chandra May 23, 2011
MEG Spectral Variations
Normalized here
Hotter than single starHighly variable
Absorption variations
Emission variations
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12 Years of Chandra May 23, 2011
Cycle-to-Cycle Comparison
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12 Years of Chandra May 23, 2011
Line Formation
Radial Velocities: lines become more blueshifted near periastron as the shock cone sweeps past the line of sight
Model showing the location of maximum emissivity of the Si XIV line along the shock boundary (Henley et al. 2008)
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12 Years of Chandra May 23, 2011
F/I ratios
Zeta Pup Eta Car
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12 Years of Chandra May 23, 2011
HETG Results Strong changes in continuum flux and lines lines of high ionization potential show smaller blueshifts than lines of
lower IP• high IP lines form close to stagnation point where electron
temperature is higher variations in centroid velocities of Si & S lines
• probably due to changing orientation of bow shock to line of sight• possible transient emission associated with RXTE flares? (Behar et
al. 2005) R=F/I ratio is above the low-density limit
• ionization from inner shell of Li-like ion in NIE plasma?• excitation to n>3 levels followed by radiative cascades?• Charge exchange?
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12 Years of Chandra May 23, 2011
Results: Iron
Broad, Variable Fe K fluorescence• X-ray scattering by wind
Fe XXV “satellite lines” which increase in strength near periastron• cooling (via conduction?) due to the growth of dense cold instabilities • dust formation?
Fe XXV & Fe K profile nearly identical in 2 near periastron observations separated by 1 cycle.
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12 Years of Chandra May 23, 2011
WR140: Shock Physics Lab
Courtesy P.M. Williams
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12 Years of Chandra May 23, 2011
2000-12-29(,D/a,)=(1.987,0.23,+44)
periastron
2006-04-01(,D/a,)=(2.649,1.77,-36)
apastron
2008-08-22(,D/a,)=(2.951,0.59,+2)
O-star
Chandra phase-dependent grating spectra of WR140
WC
O
(2009-01-25)
Courtesy Andy Pollock
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12 Years of Chandra May 23, 2011
WR140 phase-dependent MEG spectra
• T~5keV electron continuum 80%• lines 20%• WC abundances
periastron =1.987O-star =2.951
apastron =2.649
Courtesy Andy Pollock
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12 Years of Chandra May 23, 2011
XUVOIR : WR140 NeX MEG line profiles
periastron =1.987O-star =2.951
apastron =2.649
Courtesy Andy Pollock
Apastron: view flow from both sides of shock cone; velocity equilibrium?Periastron: emission from leading arm suppressed – due to changes in cooling?O-star conjunction: emission from near side of shock cone dominates
Courtesy P.M. Williams
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12 Years of Chandra May 23, 2011
Conclusions & Questions
Other Issues:• magnetic fields & collisionless plasmas• close, late-type companions• satellite lines • charge exchange
• Embedded shock emission from single stars suggest that most of the shocked gas exists deep in the wind near the wind acceleration region
• Mass loss rates need to be reduced• How general is the wavelength dependence of X-ray line opacity?• Importance of radiative instabilities/NEI effects in X-ray line formation in
binaries• change in shock physics/cooling near periastron in Eta Car and WR 140• (Very) small R ratios in long-period binaries vs. large R ratios in single stars• Evidence for ionization stratification along the shock boundary in colliding-wind
systems• No double-peaked profiles in CWBs: simple conical picture too simple?
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12 Years of Chandra May 23, 2011
END
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12 Years of Chandra May 23, 2011
X-ray Line Emission: Observed Trends
• Declining trend of X-ray ionization with stellar spectral type and weakening of H- to He-like ratios (Walborn et al. 2009)
•
dwarfs
giants
supergiants
pec.
g Cas
q1 Ori C
t Scoz Oph
HD 93250
z Pup
Walborn et al. 2009
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12 Years of Chandra May 23, 2011
Summary of Grating Observations
• how many massive stars have grating observations? (hetgs, letgs, rgs)
• how many need these observations?
Relatively small number of stars observed at high resolution, so hard to make firm conclusions regarding trends in line formation properties and connection to winds and stellar properties
Tools: TGCAT:XATLAS:http://cxc.cfa.harvard.edu/XATLAS
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12 Years of Chandra May 23, 2011
Dichotomy: 1 vs 2• Single and Binaries: different sources of emission:
I. Single stars: embedded shocks at some fraction of the wind terminal velocity. Produced by instabilities in radiative wind driving force; “clumping”
II. Binaries: Shocked gas produced by the collision of the wind of one star and that of its companion; also (I) above
Studies of X-ray emission from single and binary stars provide complementary information regarding stellar mass loss (and more generally the production of X-rays in shocks)
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12 Years of Chandra May 23, 2011
Examples: Zeta Pup & Zeta Ori• Perhaps the best-studied massive star at high X-ray spectral resolution• Zeta Pup: O4If, N overabundance compared to C, O• Zeta Ori: O9.7Ib• Strong thermal line emission• Mdot ~ 10-5 M yr-1 based on H-α line
Issues:Lines much less blueshifted and more
symmetric than expected given high Mdot Also high-temperature X-ray lines (S XV)
deep in wind; but how deep?
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12 Years of Chandra May 23, 2011
Zeta Pup Line Analysis • X-ray wind opacity: grey (large, dense clumps) vs. wavelength-dependent
(small, optically thin clumps)
• Kramer et al. (2003) analysis of HETG spectrum: X-ray optical depth nearly independent of wavelength: large, dense clumps
• Cohen et al. (2010) re-analysis, including short-wavelength lines: X-ray optical depth IS dependent on wavelength;
– requires ~factor of 3 reduction in Mdot
– lines form near 1.5 R*
• Short wavelength lines at high S/N key probes of the inner wind