Presentation is loading. Please wait.

Presentation is loading. Please wait.

Stellar Spectroscopy during Exoplanet Transits Dissecting fine structure across stellar surfaces Dainis Dravins *, Hans-Günter Ludwig, Erik Dahlén, Hiva.

Published byProsper Morrison Modified over 9 years ago

Similar presentations

Presentation on theme: "Stellar Spectroscopy during Exoplanet Transits Dissecting fine structure across stellar surfaces Dainis Dravins *, Hans-Günter Ludwig, Erik Dahlén, Hiva."— Presentation transcript:

1 Stellar Spectroscopy during Exoplanet Transits Dissecting fine structure across stellar surfaces Dainis Dravins *, Hans-Günter Ludwig, Erik Dahlén, Hiva Pazira * Lund Observatory, Sweden, www.astro.lu.se/~dainis KVA

2 STELLAR SURFACES Simulations feasible for widely different stars But … any precise physical conclusion depends on the reliability of modeling (metallicity, magnetic activity, gravitational redshift, center-to-limb wavelength changes) How does one verify/falsify 3-D simulations (except for the spatially resolved Sun) ? High-resolution spectroscopy across spatially resolved stellar disks ! Granulation on a 12,000 K white dwarf (top) and a 3,800 K red giant. Areas differ by enormous factors: 7x7 km 2 for the white dwarf, and 23x23 R Sun 2 for the giant. (H.-G. Ludwig, Heidelberg)

3  Hiva Pazira, MSc thesis, Lund Observatory (2012) Spatially resolving stellar surfaces

4 Stellar Spectroscopy during Exoplanet Transits * Exoplanets successively hide segments of stellar disk * Differential spectroscopy provides spectra of those surface segments that were hidden behind the planet * 3-D hydrodynamics studied in center-to-limb variations of line shapes, asymmetries and wavelength shifts * With sufficient S/N, also spectra of surface features such as starspots may become attainable

5 Hiva Pazira, MSc thesis, Lund Observatory (2012) Spectral line hidden by exoplanet (Rapidly rotating solar model; noise and limited spectral resolution)

6 Spatially averaged line profiles from 20 timesteps, and temporal averages. = 620 nm  = 3 eV 5 line strengths GIANT STAR T eff = 5000 K log g [cgs] = 2.5 (approx. K0 III) Stellar disk center; µ = cos  = 1.0 Line profiles from 3-D Hydrodynamic simulations Model predictions insensitive to modest spatial smearing (Models by Hans-Günter Ludwig, Landessternwarte Heidelberg)

7 (Adapted from calculations by Hans-Günter Ludwig, Landessternwarte Heidelberg) Profiles from CO 5 BOLD solar model; Five line strengths; three excitation potentials. Left: Solar disk center. Right: Disk position µ = cos  = 0.59. Synthetic line profiles across stellar disks

8 Bisectors of the same spectral line in different stars Adapted from Dravins & Nordlund, A&A 228, 203 From left: Procyon (F5 IV-V), Beta Hyi (G2 IV), Alpha Cen A (G2 V), Alpha Cen B (K1 V). Velocity [m/s] In stars with “corrugated” surfaces, convective blueshifts increase towards the stellar limb

9 Spectral lines, spatially and temporally averaged from 3-D models, change their strengths, widths, asymmetries and convective wavelength shifts across stellar disks, revealing details of atmospheric structure. These line profiles from disk center (µ = cos  = 1) towards the limb are from a CO 5 BOLD model of a main-sequence star; solar metallicity, T eff = 6800 K. (Hans-Günter Ludwig) Spectral line profiles across stellar disks

10 Line profile changes during exoplanet transit. Red: Ratios of line profiles relative to the profile outside transit. This simulation sequence from a CO 5 BOLD model predicts the behavior of an Fe I line ( 620 nm,  = 3 eV) during the first half of a transit across the stellar equator by a bloated Jupiter-size exoplanet moving in a prograde orbit, covering 2% of a main-sequence star with solar metallicity, T eff = 6300 K, rotating with V sin i = 5 km/s. Simulated line changes during exoplanet transit

11 Apparent radial velocity during transit (Rossiter-McLaughlin effect). Wavelengths (here Gaussian fits to synthetic line profiles) are shorter than laboratory values due to convective blueshift. Curves before and after mid-transit (µ = 0.21, 0.59, 0.87) are not exact mirror images due to intrinsic stellar line asymmetries. This simulation from a CO 5 BOLD model predicts the behavior of an Fe I line ( 620 nm,  = 3 eV) during a transit across the stellar equator by a bloated Jupiter-size exoplanet moving in a prograde orbit, covering 2% of a main-sequence star with solar metallicity, T eff = 6300 K, rotating with V sin i = 5 km/s. Simulated Rossiter-McLaughlin effect

12 Observations with current facilities For a few bright host stars, already current facilities, such as UVES @ VLT, permit reconstructions of stellar surface spectra, also for single stronger lines. Signatures of weaker photospheric lines require averaging over many similar ones. Improved possibilities will come once ongoing exoplanet searches find more transiting planets with bright host stars.

13 Observations with current facilities For a few bright host stars, already current facilities, such as UVES @ VLT, permit reconstructions of stellar surface spectra, also for single stronger lines. Signatures of weaker photospheric lines require averaging over many similar ones. Improved possibilities will come once ongoing exoplanet searches find more transiting planets with bright host stars.

14 Observations with current facilities For a few bright host stars, already current facilities, such as UVES @ VLT, permit reconstructions of stellar surface spectra, also for single stronger lines. Signatures of weaker photospheric lines require averaging over many similar ones. Improved possibilities will come once ongoing exoplanet searches find more transiting planets with bright host stars.

15 Observations with current facilities For a few bright host stars, already current facilities, such as UVES @ VLT, permit reconstructions of stellar surface spectra, also for single stronger lines. Signatures of weaker photospheric lines require averaging over many similar ones. Improved possibilities will come once ongoing exoplanet searches find more transiting planets with bright host stars.

16 Stellar Spectroscopy during Exoplanet Transits * Now: Marginally feasible with, e.g., UVES @ VLT * Immediate future: PEPSI @ LBT * Near future: ESPRESSO @ VLT * Future: HIRES @ E-ELT ? * Future: HIRES @ E-ELT ? Anytime soon: More exoplanets transiting bright stars Anytime soon: More exoplanets transiting bright stars

17

18 Exoplanet transit geometries G.Torres, J.Winn, M.J.Holman: Improved Parameters for Extrasolar Transiting Planets, ApJ 677, 1324, 2008

19 Work plan – HD 209458 HD 209458 selected as the most promising star for resolving spectral differences across stellar surface. Spectral type: G0 V (F9V, G0V) T eff = 6100 K (6082, 6099, 6118 ± 25 K) log g [cgs] = 4.50 (± 0.04) [Fe/H] = 0 (- 0.06, + 0.03 ± 0.02) V rot = 4.5 (± 0.5 km/s); slow rotator, comparable to Sun sin i = 1 if the star rotates in same plane as transiting planet Sufficiently similar to Sun for same spectral identifications. Somewhat hotter, lines somewhat weaker, less blending. Large planet: Bloated hot Jupiter, R = 1.38 R Jup. More vigorous convection for line differences to be detectable? Synthetic spectra for 5900 and 6250 K, log g cgs = 4.5, [Fe/H]= 0.

20

Download ppt "Stellar Spectroscopy during Exoplanet Transits Dissecting fine structure across stellar surfaces Dainis Dravins *, Hans-Günter Ludwig, Erik Dahlén, Hiva."

Similar presentations

August 22, 2006IAU Symposium 239 Observing Convection in Stellar Atmospheres John Landstreet London, Canada.

August 22, 2006IAU Symposium 239 Observing Convection in Stellar Atmospheres John Landstreet London, Canada.
 ! WAVELENGTH SHIFTS IN SOLAR-TYPE SPECTRA  ! Dainis Dravins, Lennart Lindegren, Hans-Günter Ludwig, Søren Madsen Lund Observatory, Sweden Cool Stars.

 ! WAVELENGTH SHIFTS IN SOLAR-TYPE SPECTRA  ! Dainis Dravins, Lennart Lindegren, Hans-Günter Ludwig, Søren Madsen Lund Observatory, Sweden Cool Stars.
GRAVITATIONAL REDSHIFTS versus convective blueshifts, and wavelength variations across stellar disks versus convective blueshifts, and wavelength variations.

GRAVITATIONAL REDSHIFTS versus convective blueshifts, and wavelength variations across stellar disks versus convective blueshifts, and wavelength variations.
Highest-Resolution Spectroscopy at the Largest Telescopes ? Dainis Dravins – Lund Observatory, Sweden www.astro.lu.se/~dainis.

Highest-Resolution Spectroscopy at the Largest Telescopes ? Dainis Dravins – Lund Observatory, Sweden
Exploring a Nearby Habitable World …. Orbiting an M-dwarf star Drake Deming NASA’s Goddard Space Flight Center.

Exploring a Nearby Habitable World …. Orbiting an M-dwarf star Drake Deming NASA’s Goddard Space Flight Center.
Highest-Resolution Spectroscopy at the Largest Telescopes ? Dainis Dravins – Lund Observatory, Sweden www.astro.lu.se/~dainis.

Highest-Resolution Spectroscopy at the Largest Telescopes ? Dainis Dravins – Lund Observatory, Sweden
Signatures of stellar surface structure Dainis Dravins - Lund Observatory www.astro.lu.se/~dainis KVA.

Signatures of stellar surface structure Dainis Dravins - Lund Observatory KVA.
Universe Eighth Edition Universe Roger A. Freedman William J. Kaufmann III CHAPTER 17 The Nature of Stars CHAPTER 17 The Nature of Stars.

Universe Eighth Edition Universe Roger A. Freedman William J. Kaufmann III CHAPTER 17 The Nature of Stars CHAPTER 17 The Nature of Stars.
Physics 681: Solar Physics and Instrumentation – Lecture 17 Carsten Denker NJIT Physics Department Center for Solar–Terrestrial Research.

Physics 681: Solar Physics and Instrumentation – Lecture 17 Carsten Denker NJIT Physics Department Center for Solar–Terrestrial Research.
Copyright © 2012 Pearson Education, Inc. Extrasolar Planetary Systems.

Copyright © 2012 Pearson Education, Inc. Extrasolar Planetary Systems.
Detection of Terrestrial Extra-Solar Planets via Gravitational Microlensing David Bennett University of Notre Dame.

Detection of Terrestrial Extra-Solar Planets via Gravitational Microlensing David Bennett University of Notre Dame.
Pulsations and magnetic activity in the IR Rafa Garrido & Pedro J. Amado Instituto de Astrofísica de Andalucía, CSIC. Granada.

Pulsations and magnetic activity in the IR Rafa Garrido & Pedro J. Amado Instituto de Astrofísica de Andalucía, CSIC. Granada.
Layers of the Solar Atmosphere Corona Chromosphere Photosphere Details of solar activity can be seen more easily in the hotter outer layers, which are.

Layers of the Solar Atmosphere Corona Chromosphere Photosphere Details of solar activity can be seen more easily in the hotter outer layers, which are.
The Nature of the Stars Chapter 19. Parallax.

The Nature of the Stars Chapter 19. Parallax.
Spring School of Spectroscopic Data Analyses 8-12 April 2013 Astronomical Institute of the University of Wroclaw Wroclaw, Poland.

Spring School of Spectroscopic Data Analyses 8-12 April 2013 Astronomical Institute of the University of Wroclaw Wroclaw, Poland.
What stellar properties can be learnt from planetary transits Adriana Válio Roque da Silva CRAAM/Mackenzie.

What stellar properties can be learnt from planetary transits Adriana Válio Roque da Silva CRAAM/Mackenzie.
Nadiia Kostogryz & Svetlana Berdyugina

Nadiia Kostogryz & Svetlana Berdyugina
Exoplanets Astrobiology Workshop June 29, 2006 Astrobiology Workshop June 29, 2006.

Exoplanets Astrobiology Workshop June 29, 2006 Astrobiology Workshop June 29, 2006.
Lecture 34. Extrasolar Planets. reading: Chapter 9.

Lecture 34. Extrasolar Planets. reading: Chapter 9.
Adriana V. R. Silva CRAAM/Mackenzie COROT 2005 01/11/2005.

Adriana V. R. Silva CRAAM/Mackenzie COROT /11/2005.

Similar presentations

Ads by Google