Venus is a searing inferno. Its surface temperatures are hot adequate to melt lead. Its surface pressures, 75 instances that of Earth at sea level, are adequate to crush even the hardiest of metal objects. Sulfuric acid rain falls from noxious clouds in its atmosphere that choke out even the slightest glimpse of the sky.

In a common infernal hellscape, you’d count on to locate lava—but that element appears to be missing from Venus now. Astronomers are certain that our twin planet had volcanic activity in the previous, but they’ve under no circumstances agreed if volcanoes nonetheless erupt and reshape the Venusian surface as they do Earth’s.

Now, two planetary scientists could have identified the initially proof of an active Venusian volcano hiding in 30-year-old radar scans from NASA’s Magellan spacecraft. Robert Herrick from the University of Alaska Fairbanks and Scott Hensley from NASA’s Jet Propulsion Laboratory published their breakthrough in the journal Science on March 15.  The new evaluation has excited planetary scientists, lots of of whom are now waiting for future missions to carry on the volcano hunt.

“This [study] is the initially-ever reported proof for active volcanism on yet another planet,” says Darby Dyar, an astronomer at Mount Holyoke College in Massachusetts, who wasn’t an author on the paper.

The dense Venusian clouds would hide any volcanic activity from a spacecraft in orbit. Specially honed instruments can definitely delve below the clouds, but the planet’s capricious climate tends to make probes’ lives as well quick to completely discover the grounds. Of the Soviet Venera landers of the 1960s, 1970s, and 1980s, none survived longer than about two hours.

[Related: The hellish Venus surface in 5 vintage photos]

Magellan changed that. Launched in 1989 and equipped with the finest radar that the technologies of its time could supply, Magellan mapped substantially of Venus to the resolution of a city block. In the probe’s charts, scientists identified proof of giant volcanoes, previous lava flows, and lava-constructed domes—but no smoking gun (or smoking caldera) of reside volcanic activity.

Prior to NASA crashed it into the Venusian atmosphere, Magellan produced 3 distinctive passes at mapping the planet in between 1990 and 1993, covering a distinctive chunk every time. In the approach, the probe scanned about 40 % of the planet much more than after. If the Venusian terrain had shifted in the months in between passes, scientists now may possibly locate it by comparing distinctive radar photos and spotting the distinction.

But researchers in the early 1990s didn’t have the sophisticated computer software and image-evaluation tools that their counterparts have now. If they wanted to evaluate Magellan’s maps then, they’d have had to do it manually, comparing printouts with the naked eye. So, Herrick and Hensley revisited Magellan’s information with much more sophisticated computer systems. They identified that in addition to blurriness, the probe frequently scanned the similar function from distinctive angles, creating it hard to inform actual alterations apart from, say, shadows.

“To detect alterations on the surface, we will need a fairly massive occasion, anything that disturbs roughly much more than a square kilometer of location,” Hensley says.

Sooner or later, Herrick and Hensley identified their smoking gun: a vent, just much more than a mile wide, on a previously identified mountain named Maat Mons. Among a Magellan radar image taken in February 1991 and yet another taken about eight months later, this vent appeared to have changed shape, with lava oozing out onto the nearby slopes.

To double-verify, Herrick and Hensley constructed simulations of volcanic vents primarily based on the shape of the function that Magellan had spotted. Their final results matched what Magellan saw: a prospective volcano in the approach of burping lava out onto Venus’s surface.

There is other proof that backs up their radical final results In 2012, ESA’s Venus Express mission spotted a spike in sulfur dioxide in the planet’s atmosphere, which some scientists ascribe to volcanic eruptions. In 2020, geologists identified 37 spots exactly where magma plumes from the Venusian mantle may possibly nonetheless touch its surface. But the proof has so far been circumstantial, and astronomers have under no circumstances in fact noticed a volcano in action on the “Morning Star.”

Thankfully for Venus enthusiasts, there may possibly quickly be heaps of fresh information to play with. The VERITAS space probe, element of NASA’s stick to-up to Magellan, was initially scheduled for a 2028 launch, but is now pushed back to the early 2030s due to funding difficulties. When it does lastly attain Venus, volcanoes will be close to the prime of its sightseeing list.

“We’ll be hunting for [volcanoes] in two distinctive techniques,” says Dyar, who is also deputy principal investigator on VERITAS. The spacecraft will conduct various flybys to map the whole Venusian surface once again, with radar that has one hundred instances the resolution of Magellan’s instruments (like zooming in from a city block to a single constructing). If there are volcanoes erupting across the planet, VERITAS may possibly support scientists spot the alterations that they etch into the landscape.

[Related: These scientists spent decades pushing NASA to go back to Venus]

On top of that, VERITAS will examine the Venusian atmosphere in search of fluids, which scientists contact volatiles, that volcanoes belch out as they erupt. Water vapor, for instance, is a single of the most prominent volcanic volatiles. The phosphines that elicited whispers about life on Venus in 2020 also fall into this category of molecules. (Certainly, some specialists attempted to clarify their presence by means of volcanoes).

VERITAS is not the only mission set to arrive at Earth’s infernal twin in the subsequent decade. The European Space Agency’s EnVision—scheduled for a 2031 launch—will map the planet just like VERITAS, only with even larger resolution.

VERITAS and EnVision “will have far, far improved capability to see alterations with time in a assortment of techniques through their missions,” says Herrick, who is also involved with each missions. Not only will the two make various larger-resolution scans for scientists to evaluate against every other, the final results can also be corroborated with Magellan’s antique maps, which will be 40 years in the previous by the time they arrive.

“When we get higher-resolution imagery,” Dyar says, “I feel that we’re going to locate active volcanism all more than Venus.”