Purported phosphine on Venus is more likely to be ordinary sulfur dioxide, a new study shows.
In September, a team led by astronomers in the United Kingdom announced that they had detected the chemical phosphine in the thick clouds of Venus.
The team’s reported detection, based on observations from two Earth-based radio telescopes, surprised many Venus experts.
Earth’s atmosphere contains small amounts of phosphine, which may be produced by life. Phosphine on Venus generated buzz that the planet, often succinctly touted as a “hellscape,” could somehow harbor life within its acidic clouds.
Since that initial claim, other researchers have cast doubt on the reliability of the phosphine detection. Now, a team of researchers at the University of Washington has used a robust model of the conditions within the atmosphere of Venus to revisit and comprehensively reinterpret the radio telescope observations underlying the initial phosphine claim.
As they report in a paper accepted to the Astrophysical Journal and posted to the preprint site arXiv, the group likely wasn’t detecting phosphine at all.
“Instead of phosphine in the clouds of Venus, the data are consistent with an alternative hypothesis: They were detecting sulfur dioxide,” says coauthor Victoria Meadows, a professor of astronomy. “Sulfur dioxide is the third-most-common chemical compound in Venus’ atmosphere, and it is not considered a sign of life.”
Evidence for sulfur dioxide
The researchers show that sulfur dioxide, at levels plausible for Venus, can not only explain the observations but is also more consistent with what astronomers know of the planet’s atmosphere and its punishing chemical environment, which includes clouds of sulfuric acid.
In addition, the researchers show that the initial signal originated not in the planet’s cloud layer, but far above it, in an upper layer of Venus’ atmosphere where phosphine molecules would be destroyed within seconds. This lends more support to the hypothesis that sulfur dioxide produced the signal.
Both the purported phosphine signal and this new interpretation of the data center on radio astronomy. Every chemical compound absorbs unique wavelengths of the electromagnetic spectrum, which includes radio waves, X-rays, and visible light. Astronomers use radio waves, light, and other emissions from planets to learn about their chemical composition, among other properties.
In 2017 using the James Clerk Maxwell Telescope, or JCMT, the UK-led team discovered a feature in the radio emissions from Venus at 266.94 gigahertz. Both phosphine and sulfur dioxide absorb radio waves near that frequency. To differentiate between the two, in 2019 the same team obtained follow-up observations of Venus using the Atacama Large Millimeter/submillimeter Array, or ALMA.
Their analysis of ALMA observations at frequencies where only sulfur dioxide absorbs led the team to conclude that sulfur dioxide levels in Venus were too low to account for the signal at 266.94 gigahertz, and that it must instead be coming from phosphine.
Fragile phosphine
In the current study, the researchers started by modeling conditions within Venus’ atmosphere, and using that as a basis to comprehensively interpret the features that were seen—and not seen—in the JCMT and ALMA datasets.
“This is what’s known as a radiative transfer model, and it incorporates data from several decades’ worth of observations of Venus from multiple sources, including observatories here on Earth and spacecraft missions like Venus Express,” says lead author Andrew Lincowski, a researcher with the astronomy department.
The team used that model to simulate signals from phosphine and sulfur dioxide for different levels of Venus’ atmosphere, and how those signals would be picked up by the JCMT and ALMA in their 2017 and 2019 configurations.
Based on the shape of the 266.94-gigahertz signal picked up by the JCMT, the absorption was not coming from Venus’ cloud layer, the team reports. Instead, most of the observed signal originated some 50 or more miles above the surface, in Venus’ mesosphere. At that altitude, harsh chemicals and ultraviolet radiation would shred phosphine molecules within seconds.
“Phosphine in the mesosphere is even more fragile than phosphine in Venus’ clouds,” Meadows says. “If the JCMT signal were from phosphine in the mesosphere, then to account for the strength of the signal and the compound’s sub-second lifetime at that altitude, phosphine would have to be delivered to the mesosphere at about 100 times the rate that oxygen is pumped into Earth’s atmosphere by photosynthesis.”
‘Bone-crushing’ pressure on Venus
The researchers also discovered that the ALMA data likely significantly underestimated the amount of sulfur dioxide in Venus’ atmosphere, an observation that the UK-led team had used to assert that the bulk of the 266.94-gigahertz signal was from phosphine.
“The antenna configuration of ALMA at the time of the 2019 observations has an undesirable side effect: The signals from gases that can be found nearly everywhere in Venus’ atmosphere—like sulfur dioxide—give off weaker signals than gases distributed over a smaller scale,” says coauthor Alex Akins, a researcher at the Jet Propulsion Laboratory.
This phenomenon, known as spectral line dilution, would not have affected the JCMT observations, leading to an underestimate of how much sulfur dioxide was being seen by JCMT.
“They inferred a low detection of sulfur dioxide because of that artificially weak signal from ALMA,” Lincowski says “But our modeling suggests that the line-diluted ALMA data would have still been consistent with typical or even large amounts of Venus sulfur dioxide, which could fully explain the observed JCMT signal.”
“When this new discovery was announced, the reported low sulfur dioxide abundance was at odds with what we already know about Venus and its clouds,” Meadows says.
“Our new work provides a complete framework that shows how typical amounts of sulfur dioxide in the Venus mesosphere can explain both the signal detections, and non-detections, in the JCMT and ALMA data, without the need for phosphine.”
With science teams around the world following up with fresh observations of Earth’s cloud-shrouded neighbor, the new study provides an alternative explanation to the claim that something geologically, chemically, or biologically must be generating phosphine in the clouds.
But though this signal appears to have a more straightforward explanation—with a toxic atmosphere, bone-crushing pressure, and some of our solar system’s hottest temperatures outside of the sun—Venus remains a world of mysteries, with much left for us to explore.
Additional coauthors are from Georgia Institute of Technology; the University of California, Riverside; NASA’s Caltech-based Jet Propulsion Laboratory; the NASA Goddard Space Flight Center; and the NASA Ames Research Center. The NASA Astrobiology Program funded the work, which was performed at the NExSS Virtual Planetary Laboratory.
Source: University of Washington
