Doppler Imaging & Doppler Tomography. Ilian Iliev Institute of Astronomy & Rozhen NAO

Doppler Imaging & Doppler Tomography Ilian Iliev Institute of Astronomy & Rozhen NAO

Indirect imaging of stellar surfaces and flattened structures means restoring spatial distribution of some physical parameters using time-dependent spectroscopic and/or photometric observational data. Stars: Light Curve Modeling Budding; Vogt; Strassmeier; Kjurkchieva Doppler Imaging (a.k.a. Doppler Mapping) Deutsch; Khokhlova; Vogt & Penrod; Piskunov, Accretion disks: Eclipse Mapping Horne subject of this talk Doppler Tomography Marsh, Horne, Richards,

Our Sun is the only star we can look at its surface directly.

No chances to observe spots at the same size like solar on any other star, but fortunately, there are much larger stars and spots. Strassmeier et al., 2003

The idea that other stars could also have spots is more than three centuries old. ------- Spottedness as (one of many) cause(s) for stellar variability. Stellar rotation modulates both photometric and spectroscopic behavior of the objects we observe. ------- Regular Rotation & Irregular Spots Enterprise, established 1667 Why studying spots is so important? ------- Crucial information about the stellar magnetic fields, because magnetic fields can make surface structures to appear or to vanish.

Late type active stars (RS CVn, BY Dra, FK Com, W UMa, T Tau, G-K giants, UV Cet, single MS, Algols & CVS secondaries): = cool spots because the convection is extinguished = surface structures changeable (few weeks, months, years?) = weak and complex magnetic fields (few tens of Gs, rarely observed); stellar dynamo generated fields. Early type magnetic chemically peculiar stars (Ap, Bp elemental abundances differ from solar): = abundance spots because the particle transport is restricted = surface structures stable (no changes for decades) = strong and ordered (poloidal) magnetic fields (few kgs, directly observed); fossil magnetic fields.

Doppler Imaging: to gain information about stellar surface structures from spectral line profiles and their variations due to rotation. As a spot moves across the star, line profile changes. An image of the stellar surface can be reconstructed from the observed line profile. without spot with spot Vogt & Penrod, 1983

Cool spot, temperature

Higher concentration spot, elemental abundances Kochukhov, 2005

Magnetic activity produced by the very complex inteplay between rotation and convection. => fast rotation + deep convection = large spots RS CVn stars: evolved stars in binary systems that are tidally locked. Young (PMS) stars that have not yet lost their angular momentum.

RS CVn type star Strassmeier et al.

RS CVn type star

II Peg, RS CVn type star, flip-flop activity Berdyugina et al., 1999

a 2 CVn, Ap star Kochukhov et al., 2002

HR3831, magnetic Ap star Kochukhov et al., 2004

Stars: Doppler Imaging Zeeman-Doppler Imaging Semel; Donati; Brown II Peg, RS CVn type star An extension of the temperature and abundance mapping Strassmeier et al., 2007

V374 Peg, Teff = 2900 K, ~1 kgs, solid body rotation!?! V circular polarization Donati et al., 2006

LINEAR POLARISATION CIRCULAR POLARISATION

HD24712, magnetic Ap star Lüftinger et al., 2008

AB Dor, dwarf, compact emmitting high-latitude spot Jardine et al. 2002

Velocity Distribution spherical harmonics with quantum numbers n,l,m (radial, angular, azimuthal) l = number of nodes m = number of nodes intersecting pole l-m = number of nodes parallel to equator Slide credit A. Hatzes

l = number of nodes m = number of nodes intersecting pole l-m = number of nodes parallel to equator l = 2, m = 1 l = 8, m=3 l = 3, m = 0 animations Tim Bedding

Asteroseismology

Observational constraints: Vsini ~ 10-100 km/s, i ~ 20 o - 70 o ; S/N higher is better, good phase coverage 40+ different rotational phases, S/N ~ 200-700, spectral resolution ~ 30000-50000 - 120000 and this is the ultimate price for Probably the best spatial resolution method ever used Effective spatial resolution at the equator: N res ~ 4R star Vsini/c = 10 100, or ~10-11 arcsec DVrad [m/s] = constant (S/N) 1 R 3/2 (D ) 1/2 Large, larger, and even larger telescopes, more, and even more efficient spectrographs

Power of Doppler Imaging Mapping the low latitude spots on RS CVn is the equivalent of seeing the о on 10 KČ coin from a distance of about 100 km! feat. A. Hatzes

Computer matters: Spatial restoration using line profiles is an ill-posed problem, it has no unique solution and needs additional information. = Maximum Entropy Method Vogt; Rice; Brown; Strassmeier = Tikhonov Regularization Khokhlova; Piskunov = CLEAN Kürster = Occamian Approach Berdyugina; Savanov = Radio Astronomy Approach Yankov The GOOD news is that the difference is diminished when the data used are of high quality

Tau Scorpii HOT MASSIVE STAR

SU Aur YOUNG STAR

V374 Peg Jardine & Donati

Tomography = imaging by sections, or sectioning pineapple or banana?

Tomography = to reconstruct N-dimensional object from its (N-1)-dimensional projections (or slices) Observations = to collect slices through the object or projections around it. Lunar eclipse picture credit Anthony Agiomamitis Only a spherical object can cast such a shadow: therefore, the Earth has spherical shape. Aristotle

Johann Radon (1887-1956) 3D object Radon transform 2D projection Děčín back-projections: Reconstructed image: inverse Radon transform slide credit M.T.Richards

rho=x*cos(theta)+y*sin(theta) g(x,y) ğ(x,y)

Cataclysmic Variable Stars (CVS) or Nice Things That Explode (from time to time) Close binary systems that consist of a white dwarf primary and mass transferring (donor) secondary star. Orbital periods from hours to days. Matter is transferred from donor star to the white dwarf through L1. Due to angular momentum conservation law, an accretion disk is formed. A bright spot is created in the place where the hot gas stream enters the disc. No astronomical instrument can resolve the disks optically. BUT

Earth

L1 L1 inside out

IP Peg spiral structures Schwarz et al. 2005

TT Ari disk asymmetries Stanishev et al. 2001

H-alpha Doppler Tomograms of Algols accretion ring transient disk gas stream chromosphere accretion disk Richards, 2004

Observational constraints: An old spectroscopic game: how to rise the time resolution keeping S/N and spectral resolution as-high-as-possible. Solution is not easy, not unique, and not always successful. Blurring factor 360 o t/p; t/p ~ 1/2π*ΔV/K P period, t exposure time, K feature speed, km/s ΔV spectral resolution, km/s Δφ = t/p phase resolution P = 16 hours (app. 0.7 days) t < 2.5 minutes K = 400 km/s ΔV = 6 km/s, sp.res. = 50000 Δφ < 0.003 6-m 8-m class telescopes

Danke Thank you Благодаря Díky

Most parts in CV s are moving at a few 100 to a few 1000 km/s so lines are shifted to few tens of angstroems, i.e. we can detect it With Doppler Tomography a 2D data set consisting of a time series of line profiles is then converted to a 2D Doppler tomogram A tomogram is a map of velocities without translating these into positions An intensity-distribution in the two-dimensional velocity space is created X-axis points in the direction from the accretor to the donor and the y-axis points in the direction of motion of the donor