Sept. 5, 2018


NASA Should Lead a Large Direct Imaging Mission to Study Earth-Like Exoplanets, Says New Report

WASHINGTON – To answer significant questions about planetary systems, such as whether our solar system is a rare phenomenon or if life exists on planets other than Earth, NASA should lead a large direct imaging mission – an advanced space telescope – capable of studying Earth-like exoplanets orbiting stars similar to the sun, says a new congressionally mandated report by the National Academies of Sciences, Engineering, and Medicine.

The study of exoplanets – planets outside our solar system that orbit a star – has seen remarkable discoveries in the past decade. The report identifies two overarching goals in this field of science:

Based on these goals, the committee that authored the report found that our current knowledge of the range of characteristics of planets outside the solar system is substantially incomplete.  A holistic approach to studying habitability in exoplanets, using both theory and observations, will ultimately be required to search for evidence of past and present life elsewhere in the universe. 

While the committee recognized that developing a direct imaging capability will require large financial investments and a long time scale to see results, the effort will foster the development of the scientific community and technological capacity to understand myriad worlds.  To detect a system analogous to our own Earth-sun system, the report recommends using instruments that enable direct imaging of an exoplanet by blocking the light emitted by the parent stars – such as a coronagraph or starshade.

In addition, ground-based astronomy – enabled by two U.S.-led telescopes – will also play a pivotal role in studying planet formation and potentially terrestrial worlds, the report says. The future Giant Magellan telescope (GMT) and proposed Thirty Meter Telescope (TMT) would allow profound advances in imaging and spectroscopy – absorption and emission of light – of entire planetary systems. They also could detect molecular oxygen in temperate terrestrial planets in transit around close and small stars, the report says.

The committee pointed out that the technology road map to enable the full potential of GMT and TMT in the study of exoplanets is in need of investments, and should leverage the existing network of U.S. centers and laboratories. To that end, the report recommends that the National Science Foundation invest in both telescopes and their exoplanet instrumentation to provide all-sky access to the U.S. community.

While missions like Kepler spacecraft have characterized a remarkable population of planets relatively close to their stars, our knowledge of worlds in the outer reaches of the universe is woefully lacking, the committee said. The report says WFIRST, the large space-based mission that received the highest priority in the Academies' 2010 decadal survey, will play two extremely valuable roles: first, it will permit a survey of planets farther from their stars than surveyed by Kepler and other missions. Second, it will enable a large direct imaging mission.

Although the radial velocity method – which measures the shift of the star as it orbits the center of mass of the planet system – will continue to provide essential mass and orbit information, its measurements are currently limited by variations in the surface of the star and imperfect calibration of the instruments, the report says. New instruments installed on large telescopes, substantial allocations of observing time, and collaboration between observers as well as theorists are some of the requirements for progress. To develop these methods and facilities for measuring the masses of temperate terrestrial planets orbiting sun-like stars, NASA and NSF should establish a strategic initiative in Extremely Precise Radial Velocities. 

In addition, NASA should create a mechanism to systematically collect data on exoplanet atmospheres early in the James Webb Space Telescope mission. The committee also recommended building on the model of NASA’s interdisciplinary collaboration initiative — Nexus for Exoplanet Science System – by supporting a cross-divisional research effort inviting proposals for interdisciplinary research.

The committee called on NASA to support a robust individual investigator program that includes grants for theoretical, laboratory, and ground-based telescopic investigations to fully realize the scientific payoff of exoplanet missions. The report also recognizes that discrimination and harassment exist in the scientific workforce and can affect the exoplanet research community, posing barriers to the participation of people from certain demographic groups. To maximize scientific potential and opportunities for excellence, institutions and organizations should take concrete steps to eliminate discrimination and harassment and to proactively recruit and retain scientists from underrepresented groups.

The study was sponsored by NASA.  The National Academies of Sciences, Engineering, and Medicine are private, nonprofit institutions that provide independent, objective analysis and advice to the nation to solve complex problems and inform public policy decisions related to science, technology, and medicine. They operate under an 1863 congressional charter to the National Academy of Sciences, signed by President Lincoln. For more information, visit A committee roster follows.

Riya V. Anandwala, Media Relations Officer
Andrew Robinson, Media Associate
Office of News and Public Information
202-334-2138; e-mail

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Copies of Exoplanet Science Strategy are available at or by calling 202-334-3313  or 1-800-624-6242. Reporters may obtain a copy from the Office of News and Public Information (contacts listed above).


Division on Engineering and Physical Sciences
Space Studies Board
Board on Physics and Astronomy

Committee on Exoplanet Science Strategy

David Charbonneau* (co-chair)
Professor of Astronomy
Harvard University
Cambridge, Mass.

B.Scott Gaudi (co-chair)
Thomas Jefferson Professor for Discovery and Space Exploration, and
Department of Astronomy
Ohio State University

Fabienne A. Bastien
Assistant Professor
Department of Astronomy and Astrophysics
Pennsylvania State University
University Park

Jacob Bean
Associate Professor
Department of Astronomy and Astrophysics
University of Chicago

Justin R. Crepp
Associate Professor of Physics, and
Engineering and Design Core Facility
University of Notre Dame
Notre Dame, Ind.

Eliza Kempton
Assistant Professor
Department of Astronomy
University of Maryland
College Park

Chryssa Kouveliotou*
Professor of Astrophysics
Department of Physics, and
Astronomy, Physics, and Statistics Institute of Sciences
George Washington University
Washington, D.C.

Bruce A. Macintosh
Professor of Physics
Stanford University
Stanford, Calif.

Dimitri P. Mawet
Associate Professor of Astronomy and JPL Senior Research Scientist
California Institute of Technology

Victoria S. Meadows
Department of Astronomy, and
Principal Investigator
Virtual Planetary Laboratory
University of Washington

Ruth Murray-Clay
Associate Professor, and
Associate Chair
Department of Astronomy and Astrophysics
University of California
Santa Cruz

Evgenya L. Shkolnik
Assistant Professor of Astrophysics
School of Earth and Space Exploration
Arizona State University

Ignas Snellen
Professor of Observational Astrophysics
Leiden University
Leiden, Netherlands

Alycia J. Weinberger
Staff Scientist
Department of Terrestrial Magnetism
Carnegie Institution for Science
Washington, D.C.


David B. Lang
Staff Officer

Nathan J. Boll
Staff Officer

*Member, National Academy of Sciences