NASA’s James Webb Space Telescope has topped itself once again, delivering on its promise to push the boundaries of the observable universe closer to cosmic dawn with the confirmation of a bright galaxy that existed 280 million years after the big bang. By now Webb has established that it will eventually surpass virtually every benchmark it sets in these early years, but the newly confirmed galaxy, MoM-z14, holds intriguing clues to the universe’s historical timeline and just how different a place the early universe was than astronomers expected.
“With Webb, we are able to see
farther than humans ever have before, and it looks nothing like what we
predicted, which is both challenging and exciting,” said Rohan Naidu of the
Massachusetts Institute of Technology’s (MIT) Kavli Institute for Astrophysics
and Space Research, lead author of a paper on galaxy MoM-z14 published in the
Open Journal of Astrophysics.
Due to the expansion of the universe that is driven by dark energy, discussion of
physical distances and “years ago” becomes tricky when looking this far. Using
Webb’s NIRSpec (Near-Infrared Spectrograph) instrument, astronomers confirmed
that MoM-z14 has a cosmological redshift of 14.44, meaning that its light has been
travelling through (expanding) space, being stretched and “shifted” to longer,
redder wavelengths, for about 13.5 of the universe’s estimated 13.8 billion
years of existence.
“We can estimate the distance of
galaxies from images, but it’s really important to follow up and confirm with
more detailed spectroscopy so that we know exactly what we are seeing, and when,” said Pascal
Oesch of the University of Geneva, co-principal investigator of the survey.
Image: COSMOS Field MoM-z14 Galaxy
(NIRCam Image)
NASA’s James Webb Space Telescope shows galaxy MoM-z14
as it appeared in the distant past, only 280 million years after the universe
began in the big bang.
Image: NASA, ESA, CSA, STScI, Rohan Naidu (MIT); Image
Processing: Joseph DePasquale (STScI)
Intriguing Features
MoM-z14 is one of a growing group
of surprisingly bright galaxies in the early universe – 100 times more than
theoretical studies predicted before the launch of Webb, according to the
research team.
“There is a growing chasm between
theory and observation related to the early universe, which presents compelling
questions to be explored going forward,” said Jacob Shen, a postdoctoral
researcher at MIT and a member of the research team.
One place researchers and theorists
can look for answers is the oldest population of stars in the Milky Way galaxy.
A small percentage of these stars have shown high amounts of nitrogen, which is
also showing up in some of Webb’s observations of early galaxies, including
MoM-z14.
“We can take a page from archeology
and look at these ancient stars in our own galaxy like fossils from the early
universe, except in astronomy we are lucky enough to have Webb seeing so far
that we also have direct information about galaxies during that time. It turns
out we are seeing some of the same features, like this unusual nitrogen
enrichment,” said Naidu.
With galaxy MoM-z14 existing only
280 million years after the big bang, there was not enough time for generations
of stars to produce such high amounts of nitrogen in the way that astronomers
would expect. One theory the researchers note is that the dense environment of
the early universe resulted in supermassive stars capable of producing more
nitrogen than any stars observed in the local universe.
The galaxy MoM-z14 also shows signs
of clearing out the thick, primordial hydrogen fog of the early universe in the
space around itself. One of the reasons Webb was originally built was to define
the timeline for this “clearing” period of cosmic history, which astronomers
call reionization. This is when early stars produced light of high enough energy to break
through the dense hydrogen gas of the early universe and begin travelling
through space, eventually making its way to Webb, and us. Galaxy MoM-z14
provides another clue for mapping out the timeline of reionization, work that
was not possible until Webb lifted the veil on this era of the universe.
Legacy of Discovery Continues
Even before Webb’s launch, there
were hints that something very unanticipated happened in the early universe,
when NASA’s Hubble Space Telescope discovered the bright galaxy GN-z11 400 million years after the big bang. Webb confirmed the galaxy’s distance — at the time the most distant ever. From there
Webb has continued to push back farther and farther in space and time, finding
more surprisingly bright galaxies like GN-z11.
As Webb continues to uncover more
of these unexpectedly luminous galaxies, it’s clear that the first few were not
a fluke. Astronomers are eagerly anticipating that NASA’s upcoming Nancy Grace Roman Space Telescope, with its combination of high-resolution infrared
imaging and extremely wide field of view, will boost the sample of these
bright, compact, chemically enriched early galaxies into the thousands.
“To figure out what is going on in
the early universe, we really need more information —more detailed observations
with Webb, and more galaxies to see where the common features are, which Roman
will be able to provide,” said Yijia Li, a graduate student at the Pennsylvania
State University and a member of the research team. “It’s an incredibly
exciting time, with Webb revealing the early universe like never before and
showing us how much there still is to discover.”
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 Pushes Boundaries of Observable Universe Closer to Big Bang - NASA Science
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