ExoPTF Science Uniquely Enabled by Far-IR Interferometry: Probing the   Formation of Planetary Systems, and Finding and Characterizing Exoplanets

David Leisawitz (1); Tom Armstrong (2); Chad Bender (2,3); Dominic; Benford (1); Daniella Calzetti (4); John Carpenter (5); William C. Danchi; (1); Michel Fich (6); Dale Fixsen (1,7); Daniel Y. Gezari (1); Matt Griffin; (8); Martin Harwit (9); Alan J. Kogut (1); William D. Langer (10); Charles; Lawrence (10); Dan Lester (11); Lee G. Mundy (7); Joan Najita (12); David; Neufeld (13); Goran Pilbratt (14); Stephen Rinehart (1); Aki Roberge (1,15),; Eugene Serabyn (10); Sachindev Shenoy (5,16); Hiroshi Shibai (17); Robert; Silverberg (1); Johannes Staguhn (1,7); Mark R. Swain (10); Stephen C. Unwin; (10); Edward Wright (18); and Harold W. Yorke (10) ((1) NASA GSFC; (2) Naval; Research Lab; (3) NRC Research Associate; (4) UMass Amherst; (5) Caltech; (6); UWaterloo (Canada); (7) U Maryland; (8) Cardiff U (UK); (9) Cornell; (10) Jet; Propulsion Laboratory; Caltech; (11) UT Austin; (12) NOAO; (13) Johns Hopkins; U; (14) ESA; (15) NASA Postdoctoral Fellow; (16) IPAC; (17) Nagoya U (Japan),; (18) UCLA)

arXiv:0707.0873·astro-ph·July 9, 2007·1 cites

ExoPTF Science Uniquely Enabled by Far-IR Interferometry: Probing the Formation of Planetary Systems, and Finding and Characterizing Exoplanets

David Leisawitz (1), Tom Armstrong (2), Chad Bender (2,3), Dominic, Benford (1), Daniella Calzetti (4), John Carpenter (5), William C. Danchi, (1), Michel Fich (6), Dale Fixsen (1,7), Daniel Y. Gezari (1), Matt Griffin, (8), Martin Harwit (9), Alan J. Kogut (1)

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TL;DR

A far-IR interferometer will enable groundbreaking observations of planetary system formation, exoplanet detection, and atmospheric characterization, overcoming previous technical challenges and fostering international collaboration.

Contribution

This paper highlights the scientific potential and technical feasibility of a far-IR interferometer for planetary and exoplanet studies, emphasizing its unique capabilities and international interest.

Findings

01

Far-IR interferometry can resolve structures in exoplanetary systems.

02

It can detect exoplanets via disk perturbations.

03

It enables spectroscopic analysis of exoplanet atmospheres.

Abstract

By providing sensitive sub-arcsecond images and integral field spectroscopy in the 25 - 400 micron wavelength range, a far-IR interferometer will revolutionize our understanding of planetary system formation, reveal otherwise-undetectable planets through the disk perturbations they induce, and spectroscopically probe the atmospheres of extrasolar giant planets in orbits typical of most of the planets in our solar system. The technical challenges associated with interferometry in the far-IR are greatly relaxed relative to those encountered at shorter wavelengths or when starlight nulling is required. A structurally connected far-IR interferometer with a maximum baseline length of 36 m can resolve the interesting spatial structures in nascent and developed exoplanetary systems and measure exozodiacal emission at a sensitivity level critical to TPF-I mission planning. The Space Infrared…

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Taxonomy

TopicsElectrical and Electromagnetic Research · High-pressure geophysics and materials · History and Developments in Astronomy