Proposed Missions - Terrestrial Planet Finder - NASA Planetary Photo Journal Collection

COLLECTION NAME:

NASA Planetary Photo Journal Collection

mediaCollectionId

nasaNAS~4~4

NASA Planetary Photo Journal Collection

Collection

true

Title:

Proposed Missions - Terrestrial Planet Finder

title

Proposed Missions - Terrestrial Planet Finder

Title

false

Original Caption Released with Image:

Visible Light Coronagraph for Terrestrial Planet Finder Proposed Launch: 2014 Purpose: To search for Earth-like planets that might harbor life. Terrestrial Planet Finder will use multiple telescopes working Together to take family portraits of stars and their orbiting planets and determine which planets may have the right chemistry to sustain life. The mission will study all aspects of planets, from their formation as disks of dust and gas around newly forming stars to their subsequent development. It will also look for planets orbiting the nearest stars and study their suitability as homes for any possible life. One great challenge is how to detect planets against the blinding glare of their parent star, an effort that has been compared to trying to find a firefly in the glare of a searchlight. Terrestrial Planet Finder will reduce the glare of parent stars to see planetary systems up to 50 light-years away. Using spectroscopic instruments on Terrestrial Planet Finder, scientists will measure relative amounts of gases like carbon dioxide, water vapor, ozone and methane. This study will help determine whether a planet is suitable for life--or even whether life already exists there. NASA has chosen two mission architecture concepts for further study and technology development. The two candidate architectures are: Infrared Interferometer: Multiple small telescopes on a fixed structure or on separated spacecraft flying in precision formation would simulate a much larger, very powerful telescope. A technique called nulling would reduce starlight by a factor of one million, enabling the detection of the very dim infrared emission from planets. Visible Light Coronagraph: A large optical telescope, with a mirror three to four times bigger and at least 10 times more precise than the Hubble Space Telescope, would collect starlight and the very dim light reflected from planets. Its special optics would reduce starlight by a factor of one billion, enabling astronomers to detect the faint planets. For more information, see the Terrestrial Planet Finder home page.

original_caption_released_with_image

</a> Visible Light Coronagraph for Terrestrial Planet Finder Proposed Launch: 2014 Purpose: To search for Earth-like planets that might harbor life. Terrestrial Planet Finder will use multiple telescopes working Together to take family portraits of stars and their orbiting planets and determine which planets may have the right chemistry to sustain life. The mission will study all aspects of planets, from their formation as disks of dust and gas around newly forming stars to their subsequent development. It will also look for planets orbiting the nearest stars and study their suitability as homes for any possible life. One great challenge is how to detect planets against the blinding glare of their parent star, an effort that has been compared to trying to find a firefly in the glare of a searchlight. Terrestrial Planet Finder will reduce the glare of parent stars to see planetary systems up to 50 light-years away. Using spectroscopic instruments on Terrestrial Planet Finder, scientists will measure relative amounts of gases like carbon dioxide, water vapor, ozone and methane. This study will help determine whether a planet is suitable for life--or even whether life already exists there. NASA has chosen two mission architecture concepts for further study and technology development. The two candidate architectures are: Infrared Interferometer: Multiple small telescopes on a fixed structure or on separated spacecraft flying in precision formation would simulate a much larger, very powerful telescope. A technique called nulling would reduce starlight by a factor of one million, enabling the detection of the very dim infrared emission from planets. Visible Light Coronagraph: A large optical telescope, with a mirror three to four times bigger and at least 10 times more precise than the Hubble Space Telescope, would collect starlight and the very dim light reflected from planets. Its special optics would reduce starlight by a factor of one billion, enabling astronomers to detect the faint planets. For more information, see the <a href="http://planetquest.jpl.nasa.gov/TPF/tpf_index.html">Terrestrial Planet Finder home page</a>.

Original Caption Released with Image

false

Image Credit:

NASA/JPL

image_credit

NASA/JPL

Image Credit

false

Produced By:

JPL

produced_by

JPL

Produced By

false

Mission:

Terrestrial Planet Finder

mission

Terrestrial Planet Finder

Mission

false

Instrument:

Infrared Coronagraph

instrument

Infrared Coronagraph

Instrument

false

Product Size:

2736 samples x 1836 lines

product_size

2736 samples x 1836 lines

Product Size

false

facet_what:

Earth

facet_what

Earth

facet_what

false

facet_where:

Jet Propulsion Laboratory (JPL)

facet_where

Jet Propulsion Laboratory (JPL)

facet_where

false

Image #:

PIA04499

image__

PIA04499

Image #

false

UID:

SPD-PHOTJ-PIA04499

uid

SPD-PHOTJ-PIA04499

UID

false

original url:

http://photojournal…

original_url

http://photojournal.jpl.nasa.gov/catalog/PIA04499

original url

false

MEDIA INFORMATION

Proposed Missions - Terrestrial Planet Finder