February 9, 2022
Since Parker Solar Probe captured its first visible light images of Venus’ surface from orbit in July 2020, a subsequent flyby allowed the spacecraft to gather more images, which mission scientists strung together into a video of Venus’ entire nightside. A full analysis of the images and video, published Feb. 9 in the journal Geophysical Research Letters, is adding to scientists’ understanding of the planet likened as Earth’s twin.
NASA’s Parker Solar Probe has taken its first visible light images of the surface of Venus from space.
Smothered in thick clouds, Venus’ surface is usually shrouded from sight. But in two recent flybys of the planet, Parker used its Wide-Field Imager, or WISPR, to capture the entire nightside in wavelengths of the visible spectrum — the type of light that the human eye can see — and extending into the near-infrared.
The images, combined into a video, reveal a faint glow from the surface that shows distinctive features like continental regions, plains and plateaus. A luminescent halo of oxygen in the atmosphere can also be seen surrounding the planet.
“We’re thrilled with the science insights Parker Solar Probe has provided thus far,” said Nicola Fox, director for the Heliophysics Division at NASA Headquarters. “Parker continues to outperform our expectations, and we are excited that these novel observations taken during our gravity assist maneuver can help advance Venus research in unexpected ways.”
Built and operated by the Johns Hopkins Applied Physics Laboratory (APL) in Laurel, Maryland, Parker Solar Probe uses Venus’ gravity to bend its orbit closer to the Sun. Images of the planet, often called Earth’s twin, taken during these gravity assist maneuvers can help scientists learn more about Venus’ surface geology, what minerals might be present there and the planet’s evolution. Given the similarities between the planets, this information can help scientists on the quest to understand why Venus became inhospitable and Earth became an oasis.
“Venus is the third brightest thing in the sky, but until recently we have not had much information on what the surface looked like because our view of it is blocked by a thick atmosphere,” said Brian Wood, lead author on the new study and physicist at the Naval Research Laboratory in Washington, DC. “Now, we finally are seeing the surface in visible wavelengths for the first time from space.”
Parker’s seven gravity assists each have different characteristics, as the spacecraft travels through different parts of the Venusian-induced magnetosphere and at different distances from the surface. Those where Parker Solar Probe crosses the magnetosphere behind the planet are particularly interesting scientifically, said Nour E. Raouafi, the Parker Solar Probe project scientist at APL — even though prelaunch plans did not include any planetary science at Venus.
“After the launch [in August 2018], all our observational programs changed, and the Venus observations are a great example of that,” Raouafi said. “Both imaging and in situ data we collected during the Venus gravity assists are opening our eyes on new features on the planet’s surface and atmosphere unknown to us so far.”
The first WISPR images of Venus were taken in July 2020 as Parker embarked on its third flyby. WISPR was designed to see faint features in the solar atmosphere and wind, and some scientists thought they might be able to use WISPR to image the cloud tops veiling Venus as Parker passed the planet.
“The objective was to measure the speed of the clouds,” said WISPR project scientist Angelos Vourlidas, co-author on the new paper and researcher at APL.
But instead of just seeing clouds, WISPR also saw through to the surface of the planet. The images were so striking that the scientists turned on the cameras again during the fourth pass in February 2021. During the 2021 flyby, the spacecraft’s orbit lined up perfectly for WISPR to image Venus’ nightside in entirety.
“The images and video just blew me away,” Wood said.
Clouds obstruct most of the visible light coming from Venus’ surface, but the very longest visible wavelengths, which border the near-infrared wavelengths, make it through. On the dayside, this red light gets lost amid the bright sunshine reflected off Venus’ cloud tops, but in the darkness of night, the WISPR camera was able to pick up this faint glow caused by the incredible heat emanating from the surface.
“The surface of Venus, even on the nightside, is about 860 degrees,” Wood said. “It’s so hot that the rocky surface of Venus is visibly glowing, like a piece of iron pulled from a forge.”
As it passed by Venus, WISPR picked up a range of wavelengths from 470 nanometers to 800 nanometers. Some of that light is the near-infrared — wavelengths that we cannot see, but sense as heat — but most is in the visible range, between 380 nanometers and about 750 nanometers.
In 1975, the Venera 9 lander sent the first tantalizing glimpses of the surface after landing on Venus. Since then, Venus’ surface has been revealed further with radar and infrared instruments, which can peer through the thick clouds by using wavelengths of light invisible to the human eye. NASA’s Magellan mission created the first maps in the 1990s using radar, and JAXA’s Akatsuki spacecraft gathered infrared images after reaching orbit around Venus in 2016. The new images from Parker add to these findings by extending the observations to red wavelengths at the edge of what we can see.
The WISPR images show features on the Venusian surface, such as the continental region Aphrodite Terra, the Tellus Regio plateau and the Aino Planitia plains. Because higher-altitude regions are about 85 degrees Fahrenheit cooler than lower areas, they show up as dark patches amid the brighter lowlands. These features can also be seen in previous radar images, such as those taken by Magellan.
Beyond looking at surface features, the new WISPR images will help scientists better understand the geology and mineral makeup of Venus. When heated, materials glow at unique wavelengths. By combining the new images with previous ones, scientists now have a wider range of wavelengths to study, which can help identify what minerals are on the surface of the planet. Such techniques have previously been used to study the surface of the Moon. Future missions will continue to expand this range of wavelengths, which will contribute to our understanding of habitable planets.
This information could also help scientists understand the planet’s evolution. While Venus, Earth and Mars all formed around the same time, they are very different today. The atmosphere on Mars is a fraction of Earth’s, while Venus has a much thicker atmosphere. Scientists suspect volcanism played a role in creating the dense Venusian atmosphere, but more data is needed to know how. The new WISPR images might provide clues about how volcanos may have affected the planet’s atmosphere.
In addition to the surface glow, the new images show a bright ring around the edge of the planet caused by oxygen atoms emitting light in the atmosphere. Called airglow, this type of light is also present in Earth’s atmosphere, where it’s visible from space and sometimes from the ground at night.
While Parker Solar Probe’s primary goal is solar science, the Venusian flybys are providing exciting opportunities for bonus data that wasn’t expected at the mission’s launch.
WISPR has also imaged Venus’ orbital dust ring — a doughnut-shaped track of microscopic particles strewn in the wake of Venus’ orbit around the Sun — and the FIELDS instrument made direct measurements of radio waves in the Venusian atmosphere, helping scientists understand how the upper atmosphere changes during the Sun’s 11-year cycle of activity.
In December 2021, researchers published new findings about the rediscovery of the comet-like tail of plasma streaming out behind Venus, called a “tail ray.” The new results showed this tail of particles extending nearly 5,000 miles out from the Venusian atmosphere. This tail could be how Venus’ water escaped from the planet, contributing to its current dry and inhospitable environment.
While the geometry of the next two flybys likely won’t allow Parker to image the nightside, scientists will continue to use Parker’s other instruments to study Venus’ space environment. In November 2024, the spacecraft will have a last chance to image the surface on its seventh and final flyby.
“Parker Solar Probe will fly about 200 miles [320 kilometers] from the Venusian surface,” said Raouafi. “It will be an exceptional opportunity to observe Venus and its atmosphere up close, and we are already preparing for that.”
Media contact: Michael Buckley, 240-228-7536, Michael.Buckley@jhuapl.edu
The Applied Physics Laboratory, a not-for-profit division of The Johns Hopkins University, meets critical national challenges through the innovative application of science and technology. For more information, visit www.jhuapl.edu.