Searching for Extrasolar Planets with Simultaneous Differential Imaging Eric L. Nielsen, Steward Observatory Michelson Fellow Symposium, Pasadena 2005.

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Presentation transcript:

Searching for Extrasolar Planets with Simultaneous Differential Imaging Eric L. Nielsen, Steward Observatory Michelson Fellow Symposium, Pasadena 2005

Motivation ● Imaging young, self-luminous extrasolar planets requires high contrast (>10 4 ) very close to the target star (<1”) ● Even with high-strehl AO systems reducing the size of the scattered light halo, “speckles” (diffracted light from the star), fill the inner arcsecond, greatly complicating planet detection ● This speckle noise floor does not integrate away with increased exposure time, and so must be addressed directly ● Speckle pattern is a function of time, optical path, and wavelength. ● Idea behind SDI: exploit the fact that speckles (scattered light from the star) and the planet will have very different spectral signatures.

Simultaneous Differential Imaging (SDI) ● Technique for imaging close companions at very high contrasts. ● Wollaston beam splitters produce four identical beams, passed through a quad-filter, with narrow band passes at 1.575, 1.600, and microns. Model planet spectrum from D. Sudarsky (private communication), eps Eri spectrum from Meyer et al Titan image from L. Close and M. Hartung.

Speckles with SDI Image from Laird Close and Beth Biller

SDI: Suppressing Speckle Noise Image from Laird Close and Beth Biller

Looking for AB Dor C with NACO SDI at the VLT ● With VLT adaptive optics, AB Dor C is still a 1- sigma detection after 40 minutes ● SDI allows for a very convincing detection B. Biller et al. SPIE, 2004.

SDI detection of AB Dor C ● Commissioning run of VLT SDI device in February 2004 ● Offset from AB Dor A is arcseconds (2.3 AU) ● Initial detection with standard SDI pipeline (B. Biller et al. SPIE symposium 5490 in press 2004). Companion spotted within one hour of observations. ● Immediate detection allowed follow-up spectroscopy and photometry. Image from Laird Close

Spectral Reduction ● AB Dor C is ~80 times fainter at K- band ● Offset from AB Dor A is 162 mas (6 pixels) ● Inner pixels of AB Dor A spectrum are intentionally saturated ● Derotator rotated by 180 o between exposures, allowing subtraction of AB Dor A spectrum

Spectral Reduction (Continued) ● Subtraction of 0 o and 180 o spectra removes signal from AB Dor A ● AB Dor C seen as a positive and negative signal on opposite sides of the PSF center

AB Dor C Spectral Type ● AB Dor C plotted against a series of young spectral standards, from Gorlova et al (WL14, Usco 66, 67,100) and Chauvin et al (GSC 8047) ● Sequence constrains AB Dor C between spectral types of M7 and M9.5

AB Dor Orbit Figures from Laird Close, orbital solution from Jose Guirado

AB Dor C and Evolutionary Models Figure from Laird Close

Simulating Extrasolar Planet Populations ● NACO SDI: 8.2m VLT, 200 element SH WFS, SDI ● NICI: 8.1m Gemini, 85 element curvature WFS, coronograph, SDI ● 8m ExAOC: 8m telescope, 1000 element, spatially- filtered SH WFS, coronograph, FPWFS, SDI ● GMT ExAOC: 24m GMT, 7000 element, spatially- filtered SH WFS, coronograph, FPWFS, SDI Contrast curves from Beth Biller (NACO), Gemini Request for Proposals (NICI), and Johanan Codona, Roger Angel, Laird Close, and Dan Potter (ExAOC)

Assumed Extrasolar Planet Distributions Radial velocity distributions from exoplanets.org

Simulation Results VLT NACO SDI, 40 minutes of data, 6% of planets detected GMT ExAOC, 2.8 hours of data, 35% of planets detected

Trends with Age and Distance

Target List and Properties of Detected Planets For each target star, simulate 100,000 planets, compute fraction above sensitivity curve (y-value of each point), and median value of separation between star and planet for detected planets (x-value)

Survey Design ● For each instrument, choose the best 30, 40, 50, and 60 stars based on percentage of planets that are detectable ● Best stars are observed early on in a survey, with a slower gain in planets detected as less optimal stars are observed.

Papers ● SDI – Biller, B. A., Close, L. M., Lenzen, R., Brandner, W., McCarthy, D. W., Nielsen, E. L., and Hartung, M. SPIE 5490, ● AB Dor C – Close, L. M., Lenzen, R., Guirado, J. C., Nielsen, E. L., Mamajek, E. E., Brandner, W., Hartung, M., Lidman, C., and Biller, B.A., Nature – Nielsen, E. L., Close, L. M., Guirado, J. C., Biller, B. A., Lenzen, R., Brandner, W., Hartung, M., and Lidman, C. Astron. Nachr. submitted 2005, astro-ph/ ● Planet Simulations – Nielsen, E. L., Close, L. M., and Biller, B. A., proceedings to IAUC 200, in prep 2005.

Conclusions ● The SDI technique is able to move beneath the speckle noise floor to the photon noise limit, as shown by the AB Dor C detection, making it a very powerful search method ● A survey for self-luminous, giant extrasolar planets is being conducted for young, nearby stars, using SDI cameras at the 8.2m VLT and 6.5m MMT ● Basic simulations of planet populations, extrapolating from what we already know about exoplanets, can inform survey target selection (as we're doing for the current VLT/MMT SDI survey) and design of future planet-search instruments (ability to detect planets is set largely by the inner working radius)