The broadest planned survey by NASA’s upcoming Nancy Grace Roman Space Telescope will reveal hundreds of millions of galaxies scattered across the cosmos. After Roman launches as soon as this fall, scientists will use these sparkly beacons to study the universe’s shadowy underpinnings: dark matter and dark energy.
“We set out to build the ultimate
wide-area infrared survey, and I think we accomplished that,” said Ryan Hickox,
a professor at Dartmouth College in Hanover, New Hampshire, and co-chair of the
committee that shaped the survey’s design. “We’ll use Roman’s enormous, deep 3D
images to explore the fundamental nature of the universe, including its dark
side.”
This infographic describes the High-Latitude Wide-Area
Survey that will be conducted by NASA’s Nancy Grace Roman Space Telescope. This
observation program will cover more than 5,000 square degrees (about 12 percent
of the sky) in just under a year and a half. Scientists will use the survey to
analyze hundreds of millions of galaxies scattered across the cosmos that
reveal clues about the universe’s shadowy underpinnings — dark matter and dark
energy — as well as a wealth of other science topics.
NASA’s Goddard Space Flight Center
Roman’s High-Latitude Wide-Area Survey is one of the mission’s three core observation programs. It will cover more than 5,000 square degrees (about
12 percent of the sky) in just under a year and a half. Roman will look far
from the dusty plane of our Milky Way galaxy (that’s what the “high-latitude”
part of the survey name means), looking up and out of the galaxy rather than
through it to get the clearest view of the distant cosmos.
“This survey is going to be a
spectacular map of the cosmos, the first time we have Hubble-quality imaging
over a large area of the sky,” said David Weinberg, an astronomy professor at
Ohio State University in Columbus, who played a major role in devising the
survey. “Even a single pointing with Roman needs a whole wall of 4K televisions
to display at full resolution. Displaying the whole high-latitude survey at
once would take half a million 4K TVs, enough to cover 200 football fields or
the cliff face of El Capitan.”
The survey will combine the powers
of imaging and spectroscopy to unveil a goldmine of galaxies strewn across
cosmic time. Astronomers will use the survey’s data to explore invisible dark matter, detectable only via its gravitational effects on other objects, and the
nature of dark energy — a pressure that seems to be speeding up the universe’s expansion.
“Cosmic acceleration is the biggest
mystery in cosmology and maybe in all of physics,” Weinberg said. “Somehow,
when we get to scales of billions of light years, gravity pushes rather than
pulls. The Roman wide area survey will provide critical new clues to help us
solve this mystery, because it allows us to measure the history of cosmic
structure and the early expansion rate much more accurately than we can today.”
Weighing shadows
Anything that has mass warps
space-time, the underlying fabric of the universe. Extremely massive things
like clusters of galaxies warp space-time so much that they distort the
appearance of background objects — a phenomenon called gravitational lensing.
“It’s like looking through a cosmic
funhouse mirror,” Hickox said. “It can smear or duplicate distant galaxies, or
if the alignment is just right, it can magnify them like a natural telescope.”
This simulation shows the type of science astronomers
will be able to do with future observations from NASA’s Nancy Grace Roman Space
Telescope. The sequence demonstrates how the gravity of intervening galaxy
clusters and dark matter can distort the light from farther objects, warping
their appearance. More intervening material creates stronger distortions. By
analyzing these features, astronomers can study elusive dark matter, which can
only be measured indirectly through its gravitational effects on visible
matter. As a bonus, the distortion acts like a telescope, enabling observations
of extremely distant galaxies. Simulations like this one help astronomers
understand what Roman’s future observations could tell us about the universe,
and provide useful data to validate data analysis techniques.
Caltech/IPAC/R. Hurt
Roman’s view will be large and sharp enough to study this lensing effect on
a small scale to see how clumps of dark matter warp the appearance of distant
galaxies. Astronomers will create a detailed map of the large-scale
distribution of matter — both seen and unseen — throughout the universe and
fill in more of the gaps in our understanding of dark matter. Studying how
structures grow over time will also help astronomers explore dark energy’s
strength at various cosmic stages.
“The data analysis standards
required to measure weak gravitational lensing are such that the astronomy
community as a whole will benefit from very high-quality data over the full
survey area, which will undoubtedly lead to unexpected discoveries,” said Olivier
Doré, a senior research scientist at NASA’s Jet Propulsion Laboratory in
Southern California, who leads a team focused on Roman imaging cosmology with
the High-Latitude Wide-Area Survey. “This survey will accomplish much more than
just revealing dark energy!”
While NASA’s Hubble and James Webb
space telescopes both also study gravitational lensing, the breakthrough with
Roman is its large field of view.
“Weak lensing distorts galaxy
shapes too subtly to see in any single galaxy — it’s invisible until you do a
statistical analysis,” Hickox said. “Roman will see more than a billion
galaxies in this survey, and we estimate about 600 million of them will be
detailed enough for Roman to study these effects. So Roman will trace the
growth of structure in the universe in 3D from shortly after the big bang to
today, mapping dark matter more precisely than we’ve ever done before.”
Sounding out dark energy
Roman’s wide-area survey will also
gather spectra from around 20 million galaxies. Analyzing spectra helps show
how the universe expanded during different cosmic eras because when an object
recedes, all of the light waves we receive from it are stretched out and
shifted toward redder wavelengths — a phenomenon called redshift.
By determining how quickly galaxies
are receding from us, carried by the relentless expansion of space, astronomers
can find out how far away they are — the more a galaxy’s spectrum is
redshifted, the farther away it is. Astronomers will use this phenomenon to
make a 3D map of all the galaxies measured within the survey area out to about
11.5 billion light-years away.
That will reveal frozen echoes of
ancient sound waves that once rippled through the primordial cosmic sea. For
most of the universe’s first half-million years, the cosmos was a dense, almost
uniform sea of plasma (charged particles).
Rare, tiny clumps attracted more
matter toward themselves gravitationally. But it was too hot for the material
to stick together, so it rebounded. This push and pull created waves of
pressure—sound — that propagated through the plasma.
This animation illustrates how small particles (in
this case, sand) behave when exposed to different sound frequencies. In the
very early universe, a cosmic “hum” created ripples in the primordial soup that
filled space. Since the ripples were places where more matter was collected,
like the rings of sand shown here, slightly more galaxies formed along them
than elsewhere. As the universe expanded over billions of years, so did these
structures. By comparing their size during different cosmic epochs, astronomers
can trace the universe’s expansion.
Nigel Stanford (used with permission)
Over time, the universe cooled and the waves ceased, essentially freezing
the ripples (called baryon acoustic oscillations) in place. Since the ripples
were places where more matter was collected, slightly more galaxies formed
along them than elsewhere. As the universe expanded over billions of years, so
did these structures.
These rings act like a ruler for
the universe. Today, they are about 500 million light-years wide. Roman will
precisely measure their size across cosmic time, revealing how dark energy may
have evolved.
Recent results from other
telescopes hint that dark energy may be shifting in strength over cosmic time.
“Roman will be able to make high precision tests that should tell us whether
these hints are real deviations from our current standard model or not,” said
Risa Wechsler, director of Stanford University’s KIPAC (Kavli Institute for
Particle Astrophysics and Cosmology) in California and co-chair of the
committee that shaped the survey’s design. “Roman’s imaging survey combined
with its redshift survey give us new information about the evolution of the
universe — both how it expands and how structures grow with time — that will
help us understand what dark energy and gravity are doing at unprecedented
precision.”
Altogether, Roman will help us
understand the effects of dark energy 10 times more precisely than current
measurements, helping discern between the leading theories that attempt to
explain why the expansion of the universe is speeding up.
Because of the way Roman will
survey the universe, it will reveal everything from small, rocky objects in our
outer solar system and individual stars in nearby galaxies to galaxy mergers
and black holes at the cosmic frontier over 13 billion years ago.
“Roman is exciting because it
covers such a wide area with the image quality only available in space,”
Wechsler said. “This enables a broad range of science, from things we can
anticipate studying to discoveries that we haven’t thought of
yet.”
The Nancy Grace Roman Space
Telescope is managed at NASA’s Goddard Space Flight Center in Greenbelt,
Maryland, with participation by NASA’s Jet Propulsion Laboratory in Southern
California; Caltech/IPAC in Pasadena, California; the Space Telescope Science
Institute in Baltimore; and a science team comprising scientists from various
research institutions. The primary industrial partners are BAE Systems Inc. in
Boulder, Colorado; L3Harris Technologies in Rochester, New York; and Teledyne
Scientific & Imaging in Thousand Oaks, California.
By Ashley Balzer
NASA’s
Goddard Space Flight Center, Greenbelt, Md.
Source: Core Survey by NASA’s Roman Mission Will Unveil Universe’s Dark Side - NASA
