SOFIA Helps Reveal a Destroyed Planetary System

by Anashe Bandari

Once a star evolves beyond the main sequence – the longest stage of stellar evolution, during which the radiation generated by nuclear fusion in a star’s core is balanced by gravitation – the fate of any planetary system it may have had is an enigma. Astronomers generally don’t know what happens to planets beyond this point, or whether they can even survive.

The spectral energy distribution of WD 2226-210 superposed on an image of the Helix Nebula from Hubble Space Telescope
The spectral energy distribution of WD 2226-210 superposed on an image of the Helix Nebula from Hubble Space Telescope. The plot combines optical, infrared, and millimeter photometry, the Spitzer mid-infrared spectrum, and upper limits from WISE, Spitzer, SOFIA, Herschel, and ALMA. Models of the white dwarf photosphere (solid) and IR excess showing good fits to the data detections (circles) and upper limits (triangles). Helix Nebula image credit: NOIRLab; SED credit: J. P. Marshall.

In a paper published recently in The Astronomical Journal, researchers used new data from the Stratospheric Observatory for Infrared Astronomy (SOFIA) and the Atacama Large Millimeter/submillimeter Array (ALMA), as well as archival data from the Spitzer Space Telescope and the Herschel Space Observatory, to study the Helix Nebula. These observations provide one potential explanation for the fate of these planetary remains.

A Process of Elimination, and a Disruptive Origin

The Helix Nebula is an old planetary nebula – expanding, glowing gas ejected from its host star after its main-sequence life ended. The nebula has a very young white dwarf at its center, but this central white dwarf is peculiar. It emits more infrared radiation than expected. To answer the question of where this excess emission comes from, the astronomers first determined where it could not have come from.

Collisions between planetesimals – small, solid objects formed out of cosmic dust left over from the creation of a planetary system around a star – can produce this type of excess emission, but SOFIA and ALMA failed to see the large dust grains required for such objects to exist, ruling out one option. The astronomers also didn’t find any of the carbon monoxide or silicon monoxide molecules characteristic of the gas disks that can surround evolving post-main-sequence stellar systems that precede objects like the Helix Nebula, excluding another potential explanation.

Different strands of evidence place strict constraints on the size, structure, and orbit of the source of the emission, and eventually come together to identify the same culprit: dust – from full-fledged planets destroyed during the nebula’s formation – returning toward its inner regions.

“In piecing together the size and shape of the excess emission, and what those properties infer regarding the dust grains in the white dwarf environment, we conclude that a disrupted planetary system is the best solution to the question of how the Helix Nebula’s infrared excess was created and maintained,” said Jonathan Marshall, the lead author on the paper and a researcher at Academia Sinica in Taiwan.

Once they realized the remnants of a former planetary system are at the origin of the infrared emission, they calculated how many grains need to be returning to the Helix Nebula’s center to account for the emission: about 500 million over the 100,000-year lifetime of the planetary nebula, conservatively.

SOFIA’s Role

SOFIA’s capabilities fell right into a gap between the previous Spitzer and Herschel observations, allowing the group to understand the shape and brightness of the dust, and improving the resolution of how far it spreads out.

“This gap lay around where we expected the dust emission to peak,” Marshall said. “Pinning down the shape of the dust emission is vital to constraining the properties of the dust grains that produce that emission, so the SOFIA observation helped refine our understanding.”

Though the researchers are not planning any follow-up observations of the Helix Nebula in particular, this study is a piece in a larger effort to use observations to understand what happens to planetary systems once their star evolves past the main sequence. The group hopes to study other late-stage stars using similar techniques.

SOFIA was a joint project of NASA and the German Space Agency at DLR. DLR provided the telescope, scheduled aircraft maintenance, and other support for the mission. NASA’s Ames Research Center in California’s Silicon Valley managed the SOFIA program, science, and mission operations in cooperation with the Universities Space Research Association, headquartered in Columbia, Maryland, and the German SOFIA Institute at the University of Stuttgart. The aircraft was maintained and operated by NASA’s Armstrong Flight Research Center Building 703, in Palmdale, California. SOFIA achieved full operational capability in 2014 and concluded its final science flight on Sept. 29, 2022.

SOFIA Helps Complete Picture on Molecular Cloud Formation

by Anashe Bandari

Molecular clouds — clumps of gas and dust in space, where molecules form — make up the densest regions of the Milky Way, but how they assemble is largely unknown: Some theories point to a slow, long process, while others suggest a fast, dynamic one.

Composite image of Cygnus X obtained by NASA’s Spitzer Space Telescope, with SOFIA’s upGREAT ionized carbon data overlaid in blue, green, and red
Composite image of Cygnus X obtained by NASA’s Spitzer Space Telescope, with SOFIA’s upGREAT ionized carbon data overlaid in blue, green, and red. The three colors represent material moving at different velocities: -10 to 4 km/s for blue, 4-12 km/s for green, and 12-20 km/s for red. Credit: NASA/JPL-Caltech/SOFIA

A recent study, published in Nature Astronomy, used data from the Stratospheric Observatory for Infrared Astronomy (SOFIA)’s upGREAT instrument to observe ionized carbon emission from molecular clouds in the Cygnus X region, one of the most massive star formation regions in the Milky Way. The astronomers, led by Nicola Schneider, a researcher at the University of Cologne in Germany, found areas of diffuse gas surrounding two molecular clouds are colliding very rapidly, creating a dense region in which new stars can form.

“Before this, there was a lot of uncertainty and debate on the timescale of cloud formation, because it is extremely difficult to observe,” said Lars Bonne, a postdoctoral research associate at SOFIA and author on the recent paper. “This is direct evidence of how it’s actually going: It’s fast!”

For decades, most processes in the interstellar medium were thought to take place on timescales of around 10 million years or more, but this high-velocity flow is leading to materials assembling in only about 1.2 million years ­— fast, as Bonne said.

Previous studies have shown that a very similar process is also at work in low-mass clouds. Coupled with these previous findings, this first observation of cloud collision in such a massive region helps complete the picture. Together, the studies indicate a degree of universality: Both smaller and more major cloud collision events that lead to star formation are now known to be quick.

This study also provides the first evidence that ionized carbon can unveil the interactions between molecular clouds. The group used data from SOFIA’s FEEDBACK program, which created large maps of ionized carbon in the Milky Way’s clouds. Schneider, Bonne, and their collaborators plan to continue to explore the FEEDBACK data to see if they can find similar processes occurring in other giant molecular clouds.

SOFIA was a joint project of NASA and the German Space Agency at DLR. DLR provided the telescope, scheduled aircraft maintenance, and other support for the mission. NASA’s Ames Research Center in California’s Silicon Valley managed the SOFIA program, science, and mission operations in cooperation with the Universities Space Research Association, headquartered in Columbia, Maryland, and the German SOFIA Institute at the University of Stuttgart. The aircraft was maintained and operated by NASA’s Armstrong Flight Research Center Building 703, in Palmdale, California. SOFIA achieved full operational capability in 2014 and concluded its final science flight on Sept. 29, 2022.