海角大神

Venus seems like the last place where any creature would make its home.

A thick, extremely acidic cloud layer enshrouds that rocky planet, trapping so much heat that the surface is roughly 900 degrees Fahrenheit. That鈥檚 more than hot enough to melt lead. As such, our neighboring planet has earned nicknames like 鈥渉ellscape鈥� and 鈥淓arth鈥檚 evil twin.鈥�

But this week, sweltering Venus became a surprising hot topic in humanity鈥檚 quest to find extraterrestrial life. On Monday, a team of researchers revealed in published in the journal Nature Astronomy that they had spotted something that just might indicate that some sort of life resides in those toxic Venusian clouds.聽

Did they actually find aliens?聽

Not exactly. What they spotted was the fingerprints of a gas that, according to everything we know about Venus, shouldn鈥檛 be there unless something 鈥� or someone 鈥� was actively producing it. And on Earth, that gas, known as phosphine, is produced by microorganisms.聽

鈥淚t鈥檚 cool to think that it might be life, but the real thing is this is just a strange thing that we found that has some really cool implications that we need to learn more about,鈥� says Paul Rimmer, a co-author of the new paper and an astrochemist at the University of Cambridge in Britain. 鈥淲hatever explains this feature, it鈥檚 something weird.鈥�

Finding evidence of phosphine in the Venusian cloud bank thrusts the planet into the spotlight anew. This discovery also informs our search for habitable worlds outside our solar system, serving as a reminder that life on another world could look very different from the life we know here on Earth.聽

鈥淲e have essentially always considered Venus to be an uninhabitable world because of its incredibly high surface temperatures and its inhospitable sulfuric acid clouds and its ionizing environment, being closer to the sun, etcetera,鈥� says Michael Way, an astronomer at the NASA Goddard Institute for Space Studies. So if closer scrutiny of the planet reveals that there is indeed life in Venus鈥� clouds, it could be a 鈥済ame changer,鈥� he says. 鈥淚f it鈥檚 true, it makes us reevaluate what habitability means and the robustness of life-forms.鈥�

Whittling down the possibilities

When Dr. Rimmer initially saw the data that bore a fingerprint of phosphine, his first thought was that it had to be something else. The colleagues that showed him that initial data might鈥檝e been mistaken. That much phosphine shouldn鈥檛 be there.

Still, he was intrigued, so he joined the team and together they took another look with a different telescope. Sure enough, that phosphine fingerprint showed up again in the new data. And although it鈥檚 possible that the data could be indicating the presence of a molecule that scientists don鈥檛 yet know exists, says Dr. Rimmer, among known molecules, this signal is unique to phosphine.

But could phosphine only exist there if life does, too? Phosphine does appear elsewhere in the solar system,聽such as in the atmospheres of Jupiter and Saturn, likely without biology. Rather, scientists think it forms deep in those gas giants鈥� atmospheres at extremely high pressures and temperatures 鈥� conditions that don鈥檛 exist on a smaller rocky planet like Venus or Earth. On Earth, phosphine is produced industrially or by microbes (specifically bacteria involved in decomposition).

鈥淚t鈥檚 been an exploration of the unknown,鈥� Dr. Rimmer says of the study. 鈥淭he only known molecule that can cause that [spectral signature] is phosphine. The only known explanation for the concentration is life. But so little is known about the nature of phosphine, and so much is unknown about the constitution of the atmosphere of Venus. And so it really does bring you face-to-face with your own ignorance.鈥�

What would Venusian life even look like?

In the quest to find life on another world, scientists only have one model of what to look for: Earth.

鈥淎s scientists, of course we have to be open-minded about what life might be like. But you鈥檝e got to start somewhere,鈥� says Laura Kreidberg, director of the Atmospheric Physics of Exoplanets department at the Max Planck Institute for Astronomy.聽

Venus may be a harshly hot and forbidding world today, but planetary scientists say it wasn鈥檛 always that way. Early Venus was likely quite a bit like early Earth. Sometime in its history, something made our once-twin take a different path.

Many scientists think it might have happened quite early in Venus鈥� history, says Dr. Way. But he has another idea: The surface of the planet might have been habitable for an extended period of time.

鈥淚t鈥檚 possible,鈥� Dr. Way says, 鈥渋t could have had surface liquid water oceans for, maybe, a few millions of years, hundreds of millions years, even as long as a couple billion years. And that something else happened to the planet later on in life that put it in the state that we see today.鈥�

Dr. Way鈥檚 current hypothesis, described in , is that some sort of extreme volcanism kicked off climate change of epic proportions on Venus, perhaps as recently as 700 million years ago. That event thrust carbon dioxide into the atmosphere, heating up the planet enough for its oceans to boil off into the atmosphere. And, given that water vapor is a powerful greenhouse gas, Venus would鈥檝e just gotten hotter and hotter as all of its liquid water boiled off, thrusting it into a wildly different climatic state.

If Venus ever had flowing oceans, it could鈥檝e possibly hosted some form of life at that time. But scientists agree that life probably couldn鈥檛 survive the intense heat on the dry surface today.聽

What about those cloud banks? The thinking goes that perhaps some tough survivors may have escaped Venus鈥� surface on . However, those clouds seem to be intensely toxic.

鈥淭hese droplets are 90% sulfuric acid. They鈥檙e more acidic than any body of water on Earth,鈥� Dr. Rimmer says. 鈥淚t鈥檚 not quite right to even call it water when it鈥檚 90% sulfuric acid.鈥�

On Earth, biological material gets destroyed by that much acidity. Sure, there have been extremophiles found residing in incredibly acidic conditions, like the聽, but never in any place even remotely as acidic as Venus鈥� clouds.

Still, Dr. Way says, it might be that 鈥渆volution finds a way.鈥�

鈥淎s the planet transitions into this 鈥榠nhabitable鈥� state,鈥� he says, if it doesn鈥檛 happen too quickly, it might be that 鈥渓ife has a chance to evolve along with it, in a way.鈥�

A case study for exoplanets

To researchers searching for signs of life on distant worlds outside our solar system, this week鈥檚 news means Venus could provide an exciting opportunity.

鈥淭he holy grail of my whole research field is searching for signs of life in the atmospheres of other planets,鈥� says Dr. Kreidberg, who studies planets orbiting stars other than our own sun, called exoplanets.聽

Those signs of life are called biosignatures, substances (like phosphine) that scientists think can only exist in a given environment if life is there, too. But when it comes to exoplanets, we don鈥檛 have the technology to go check it out up close.

But Venus is right next door.聽

鈥淭he really exciting thing is that we get to explore these questions in our own backyard,鈥� she says. 鈥淲e have the opportunity to actually go to the planet and learn in a lot more detail what鈥檚 happening in its atmosphere.鈥�

NASA hasn鈥檛 sent a dedicated mission to Venus since the Magellan orbiter launched in 1989, and since then, the planet has mostly been observed by telescopes or as a spacecraft flew by on its way to another destination. The Japan Aerospace Exploration Agency (JAXA) does currently have an orbiter around Venus, but the last spacecraft to dip into the planet鈥檚 atmosphere was the Soviet Union鈥檚 Vega 2 in 1985.

鈥淧eople like me, and others working in this discipline much longer than me, have been begging for in situ missions to Venus for decades,鈥� Dr. Way says. 鈥淎nd if this brings that, then all the better. Let鈥檚 go back to Venus.鈥�