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Why Roman Space Telescope?

Scheduled to launch in the mid-2020s, the Nancy Grace Roman Space Telescope will function as Hubble’s wide-eyed cousin. While just as sensitive as Hubble's cameras, Roman Space Telescope's 300-megapixel Wide Field Instrument will image a sky area 100 times larger. This means a single Roman Space Telescope image will hold the equivalent detail of 100 pictures from Hubble.

The mission’s wide field of view will allow it to generate never-before-seen big pictures of the universe, which will help astronomers explore some of the greatest mysteries of the cosmos, including why the expansion of the universe seems to be accelerating. One possible explanation for this speed-up is dark energy, an unexplained pressure that currently makes up 68 percent of the total content of the cosmos and may have been changing over the history of the universe. Another possibility is that this apparent cosmic acceleration points to the breakdown of Einstein’s general theory of relativity across large swaths of the universe. Roman Space Telescope will have the power to test both of these ideas.

To learn more about dark energy, Roman Space Telescope will use its powerful 2.4-meter mirror and Wide Field Instrument to do two things: map how matter is structured and distributed throughout the cosmos and measure how the universe has expanded over time. In the process, the mission will study galaxies across cosmic time, from the present back to when the universe was only half a billion years old, or about 4 percent of its current age.

Roman Space Telescope will do this through multiple observational strategies, including surveys of exploding stars called supernovae and galaxy clusters, and mapping out the distribution of galaxies in three dimensions. Measuring the brightness and distances of supernovae provided the first evidence for the presence of dark energy. Roman Space Telescope will extend these studies to greater distances to measure how dark energy's influence increased over time.

Roman Space Telescope will measure precise distances to galaxy clusters to map how they grew over time. The mission will also pinpoint the distances to millions of galaxies by measuring how their light becomes redder at greater distances, a phenomenon called redshift. The farther off a galaxy is, the redder its light appears when we see it. Mapping out the 3-D positions of galaxies will allow astronomers to measure how the distribution of galaxies has changed over time, providing another measure of how dark energy has affected the cosmos.

The Wide Field Instrument will also allow Roman Space Telescope to measure the matter in hundreds of millions of distant galaxies through a phenomenon dictated by Einstein’s relativity theory. Massive objects like galaxies curve space-time in a way that bends light passing near them, creating a distorted, magnified view of far-off galaxies behind them. Using this magnifying glass effect, called weak gravitational lensing, Roman Space Telescope will paint a broad picture of how matter is structured throughout the universe, allowing scientists to put the governing physics of its assembly to the ultimate test.

Roman Space Telescope can use this same light-bending phenomenon to study planets beyond our solar system, known as exoplanets. In a process called microlensing, a foreground star in our galaxy acts as the lens. When its motion randomly aligns with a distant background star, the lens magnifies, brightens and distorts the background star. As the lensing star drifts along in its orbit around the galaxy and the the alignment shifts, so does the apparent brightness of the star. The precise pattern of these changes can reveal planets orbiting the lensing star because the planets themselves serve as miniature gravitational lenses. Such alignments must be precise and last only hours.

Roman Space Telescope's microlensing survey will monitor 100 million stars for hundreds of days and is expected to find about 2,500 planets, with significant numbers of rocky planets in and beyond the region where liquid water may exist. This planet-detection method is sensitive enough to find planets smaller than Mars, and will reveal planets orbiting their host stars at distances ranging from closer than Venus to beyond Pluto. These results will make Roman Space Telescope an ideal companion to missions like NASA's Kepler and the upcoming Transiting Exoplanet Survey Satellite (TESS), which are best suited to find larger planets orbiting closer to their host stars. Together, discoveries from these three missions will help complete the census of planets beyond our solar system, helping us learn how planets form and migrate into systems like our own.

Roman Space Telescope will also feature a coronagraph technology demonstration instrument designed to directly image exoplanets by blocking out a star’s light, allowing the much fainter planets to be observed. As NASA’s first advanced coronagraph in space, it will be 1,000 times more capable than any previously flown.

Roman Space Telescope will serve as an important tool for the science community through its General Observer programs. All Roman Space Telescope data will be publicly available immediately after processing and delivery to the archive. Also, by submitting proposals through the competitive program, scientists around the world will be able to use the observatory to study the cosmos in their own way, from the nearest exoplanets out to clusters of distant galaxies.

By pioneering an array of innovative technologies, Roman Space Telescope will serve as a multipurpose mission, furnishing a big picture of the universe and helping us answer some of the most profound questions in astrophysics, such as how the universe evolved into what we see today, and what is its ultimate fate.


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