Using NASA’s James Webb Space Telescope, astronomers have spotted two rare kinds of dust in the dwarf galaxy Sextans A, one of the most chemically primitive galaxies near the Milky Way. The finding of metallic iron dust and silicon carbide (SiC) produced by aging stars, along with tiny clumps of carbon-based molecules, shows that even when the universe had only a fraction of today’s heavy elements, stars and the interstellar medium could still forge solid dust grains. This research with Webb is reshaping ideas about how early galaxies evolved and developed the building blocks for planets, as NASA explores the secrets of the universe and our place in it.
Sextans A lies about 4 million
light-years away and contains only 3 to 7 percent of the Sun’s metal content,
or metallicity, the astrophysical term for elements heavier than hydrogen and
helium. Because the galaxy is so small, unlike other nearby galaxies, its
gravitational pull is too weak to retain the heavy elements like iron and
oxygen created by supernovae and aging stars.
Galaxies like it resemble those
that filled the early universe just after the big bang, when the universe was
made of mostly hydrogen and helium, before stars had time to enrich space with
‘metals.’ Because it is relatively close, Sextans A gives astronomers a rare
chance to study individual stars and interstellar clouds under conditions
similar to those shortly after the big bang.
“Sextans A is giving us a blueprint
for the first dusty galaxies,” said Elizabeth Tarantino, postdoctoral
researcher at the Space Telescope Science Institute and lead author of the
results in one of the two studies presented at a press conference at the 247th
meeting of the American Astronomical Society in Phoenix. “These results help us
interpret the most distant galaxies imaged by Webb and understand what the
universe was building with its earliest ingredients.”
Image A: Sextans A PAHs Pull-out
(NIRCam and MIRI Image)
Images from NASA’s James Webb Space Telescope of the
dwarf galaxy Sextans A reveal polycyclic aromatic hydrocarbons (PAHs), large
carbon-based molecules that can be a signifier of star formation. The inset at
the top right zooms in on those PAHs, which are represented in green.
Image: NASA, ESA, CSA, Elizabeth Tarantino (STScI),
Martha Boyer (STScI), Julia Roman-Duval (STScI); Image Processing: Alyssa Pagan
(STScI)
Forging dust without usual
ingredients
One of those studies, published in the Astrophysical Journal, honed in on a half a dozen stars with the
low-resolution spectrometer aboard Webb’s MIRI (Mid-Infrared Instrument). The
data collected shows the chemical fingerprints of the bloated stars very late
in their evolution, called asymptotic giant branch (AGB) stars. Stars with
masses between one and eight times that of the Sun pass through this phase.
“One of these stars is on the
high-mass end of the AGB range, and stars like this usually produce silicate
dust. However, at such low metallicity, we expect these stars to be nearly
dust-free,” said Martha Boyer, associate astronomer at the Space Telescope
Science Institute and lead author in that second companion study. “Instead,
Webb revealed a star forging dust grains made almost entirely of iron. This is
something we’ve never seen in stars that are analogs of stars in the early
universe.”
Silicates, the usual dust formed by
oxygen-rich stars, require elements like silicon and magnesium that are almost
nonexistent in Sextans A. It would be like trying to bake cookies in a kitchen
without flour, sugar, and butter.
A normal cosmic kitchen, like the
Milky Way, has those crucial ingredients in the form of silicon, carbon, and
iron. In a primitive kitchen, like Sextans A, where almost all of those
ingredients are missing, you barely have any proverbial flour or sugar.
Therefore, astronomers expected that without those key ingredients, stars in
Sextans A couldn’t “bake” much dust at all.
However, not only did they find
dust, but Webb showed that one of these stars used an entirely different recipe
than usual to make that dust.
The iron-only dust, as well as
silicon carbide produced by the less massive AGB stars despite the galaxy’s low
silicon abundance, proves that evolved stars can still build solid material
even when the typical ingredients are missing.
“Dust in the early universe may
have looked very different from the silicate grains we see today,” Boyer said.
“These iron grains absorb light efficiently but leave no sharp spectral
fingerprints and can contribute to the large dust reservoirs seen in far-away
galaxies detected by Webb.”
Image B: Sextans A Context Image
(Webb and KPNO)
NASA’s James Webb Space Telescope’s image of a portion
of the nearby Sextans A galaxy is put into context using a ground-based image
from the Nicholas U. Mayall 4-meter Telescope at Kitt Peak National
Observatory.
Image: STScI, NASA, ESA, CSA, KPNO, NSF's NOIRLab,
AURA, Elizabeth Tarantino (STScI), Phil Massey (Lowell Obs.), George Jacoby
(NSF, AURA), Chris Smith (NSF, AURA); Image Processing: Alyssa Pagan (STScI),
Travis Rector (UAA), Mahdi Zamani (NSF's NOIRLab), Davide De Martin (NSF's
NOIRLab)
Tiny clumps of organic molecules
In the companion
study, currently
under peer review, Webb imaged Sextans A’s interstellar medium and discovered
polycyclic aromatic hydrocarbons (PAHs), which are complex, carbon-based
molecules and the smallest dust grains that glow in infrared light. The
discovery means Sextans A is now the lowest-metallicity galaxy ever found to
contain PAHs.
But, unlike the broad,
sweeping PAH emission seen in metal-rich galaxies, Webb revealed PAHs in tiny, dense
pockets only a few light-years across.
“Webb shows that PAHs can form and
survive even in the most metal-starved galaxies, but only in small, protected
islands of dense gas,” said Tarantino.
The clumps likely represent regions
where dust shielding and gas density reach just high enough to allow PAHs to
form and grow, solving a decades-long mystery about why PAHs seem to vanish in
metal-poor galaxies.
The team has an approved Webb Cycle 4 program to use high-resolution spectroscopy to study the
detailed chemistry of Sextans A’s PAH clumps further.
Image C: Giant Star in Dwarf Galaxy
Sextans A (Spectrum)
This graph shows a spectrum of an Asymptotic Giant
Branch (AGB) star in the Sextans A galaxy. It compares data collected by NASA’s
James Webb Space Telescope with models of mostly silicate-free dust and dust
containing at least 5% silicates.
Illustration: NASA, ESA, CSA, STScI, Joseph Olmsted
(STScI)
Connecting two discoveries
Together, the results show that the
early universe had more diverse dust production pathways than the more
established and proven methods, like supernova explosions. Additionally,
researchers now know there’s more dust than predicted at extremely low metallicities.
“Every discovery in Sextans A
reminds us that the early universe was more inventive than we imagined,” said
Boyer. “Clearly stars found a way to make the building blocks of planets long
before galaxies like our own existed.”
The James Webb Space Telescope is
the world’s premier space science observatory. Webb is solving mysteries in our
solar system, looking beyond to distant worlds around other stars, and probing
the mysterious structures and origins of our universe and our place in it. Webb
is an international program led by NASA with its partners, ESA (European Space
Agency) and CSA (Canadian Space Agency).
To learn more about Webb, visit: https://science.nasa.gov/webb
Source: NASA Webb Finds Early-Universe Analog's Unexpected Talent for Making Dust - NASA Science
