Tuesday, March 2

What New Horizons Found in Deep Space — And Why It Matters

What New Horizons Found in Deep Space — And Why It Matters

Point a telescope at a square of space and you’re liable to see something — stars, galaxies, interstellar gas. Now, subtract everything you already know about, and you ought to see nothing — black space. Right?

Wrong, according to scientists on the New Horizons team. The spacecraft that flew by Pluto, Charon, and another Kuiper Belt object named Arrokoth has now turned its camera to far-off vistas, only to discover that there’s more light there than we expected. That could have huge implications if it pans out, but tallying all the universe’s light sources gets a bit complicated.

How Dark Is Space?

Team member Tod Lauer (NSF’s NOIRLab) and his colleagues used data collected by the New Horizons Long Range Reconnaissance Imager (LORRI) camera to snap 195 30-second exposures in seven regions above and below the star-filled galactic plane.

New Horizons imaging regions
New Horizons imaged seven regions above and below the star-filled galactic plane.
Lauer et al. / Astrophysical Journal 2021

They’re using New Horizons because the sky the spacecraft sees is 10 times darker than the one at Earth. Unlike the outer solar system, there’s a lot of dust near Earth and it scatters the Sun’s light in every direction, even backward. Ground-based observers see this dust-scattered sunlight as the zodiacal light, and it has muddled previous attempts to measure the cosmic optical background (COB).

Like the more famous cosmic microwave background astronomers measure the COB in two steps: image patches of sky, then subtract the light from all known sources. From New Horizons’ relatively dust-free vantage point, there’s one less component that astronomers have to subtract.

New Horizons images
The New Horizons images were of deep space but still contained a few galactic stars and background galaxies.
Lauer et al. / Astrophysical Journal 2021

There’s still lots of visible light sources to deal with, though: stars and galaxies themselves must be subtracted out of the image, as does light from stars and galaxies that are outside the field of view, but whose light scatters onto the camera. Then there’s the stars and galaxies that are too faint for the camera to resolve — those are removed with the aid of computer simulations.

Finally, they subtracted the contribution from all of the Milky Way’s stars, whose light scatters off interstellar dust, basing the calculations on observations of galactic cirrus.

But even after accounting for everything that astronomers know makes and scatters visible light, the New Horizons team was left with “extra” light that they still couldn’t explain. Lauer and colleagues called this component a “diffuse cosmic optical background” in the January 10th Astrophysical Journal.

Contributions to the cosmic optical background
When the astronomers tallied up all the possible sources (marked by colored bars) that could contribute to the visible-light background they had measured in each of the seven images, they couldn’t account for all of what they had measured (black crosses).
Lauer et al. / Astrophysical Journal 2021

“The total unknown amount is more than the integrated flux from all known galaxies,” Lauer said, presenting the results at the 237th meeting of the American Astronomical Society.

A Universe Half Empty, or Half Full?

If you’ve read other coverage about these results, you might be scratching your head at this point. NASA’s press release led to headlines claiming that the universe has far fewer galaxies than thought. But that depends on who you ask.

A little more than four years ago, Christopher Conselice (then at University of Nottingham, UK) calculated the total number of galaxies in the universe based on those found in the Hubble Ultra Deep Field (HUDF). Extrapolating to extremely faint magnitudes, he and his colleagues concluded that Hubble had missed 90% of the galaxies in the visible universe, which they estimated tally up to 2 trillion. That would suggest that there are 10 times more galaxies than are accounted for in existing surveys.

Section of the Hubble Ultra Deep Field
A section of the Hubble Ultra Deep Field shows a dizzying array of galaxies. But many galaxies are beyond even Hubble’s sensitivity. The question is, how many is Hubble missing?
NASA / ESA / H. Teplitz / M. Rafelski (IPAC / Caltech) / A. Koekemoer (STScI) / R. Windhorst (Arizona State University) / Z. Levay (STScI)

What the New Horizons team found revises that estimate significantly downward — at most the Ultra Deep Field is only missing 50% of known galaxies. But that would still mean there are hundreds of billions of them, twice as many as currently cataloged.

What Makes “Extra” Light?

Whether all this “extra” light comes from unknown galaxies isn’t actually clear. All astronomers can say right now is that there’s a source of light that existing catalogs of stars and galaxies don’t capture.

Some of the excess may yet find a simple explanation as astronomers dig into the details. Shuji Matsuura (Kwansei Gakuin University, Japan), who also found an indication of  “extra” light with his colleagues in the Cosmic Infrared Background Experiment (CIBER), suggested that the New Horizons team might have underestimated the contribution from scattered Milky Way light.  

“My opinion,” he adds, “is that we have to be careful to claim the existence of the diffuse cosmic optical background at this stage.”

Even if the result pans out, there are plenty of other sources of unaccounted light besides faint galaxies. Perhaps astronomers haven’t not properly included the light from galaxies’ faint stellar halos. Or maybe there are more “lost” stars than we thought, tugged away from their home galaxies during mergers and now floating in intergalactic space.

Deep image of NGC 891
A deep image of edge-on spiral NGC 891, captured by R. Jay GaBany from his Black Bird II Observatory, reveals the faint light of stars on the galaxy’s outer edges. Some of the “extra” background light astronomers are seeing could come from unaccounted for stellar halos and even “lost” stars that have left their galaxies for good.

There’s also the possibility that there’s something unexpected out there, such as undiscovered black holes or even axions, a proposed (but still hypothetical) dark matter particle.

Future observations from space will shed more, ahem, light: Matsuura notes that the CIBER team plans to launch an additional sounding rocket to study the near-infrared background in more detail. And coauthor Marc Postman (STScI) stated at the AAS that while New Horizons has delivered the first successful (albeit “off-label”) outer solar system measurement of the COB, future planetary probes could make such a measurement part of their mission.


Published at Mon, 25 Jan 2021 14:00:00 +0000