Estevan Guzman one of the Astronomical Illustrator / Animators at Griffith Observatory joins us to talk about cosmic art created by science and its impact on the industry.
Space news topics covered:
Was the “WOW! Signal” a Comet? Probably not… Darpa selects XS-1 partner & X-37B gets a new launcher China Tests “Spooky Action At A Distance” in Space Asteroid Redirect winds down, Deep Space Gateway gains support Hubble sees waltzing dwarf stars
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Here is a NASA article about how artists create imagery of planets around other stars realistically despite the fact no one has ever seen such an exoplanet up close:
The moon hanging in the night sky sent Robert Hurt’s mind into deep space — to a region some 40 light years away, in fact, where seven Earth-sized planets crowded close to a dim, red sun.
This artist’s concept shows what each of the TRAPPIST-1 planets may look like, based on available data about their sizes, masses and orbital distances. Credits: NASA/JPL-Caltech Full image and caption
Hurt, a visualization scientist at Caltech’s IPAC center, was walking outside his home in Mar Vista, California, shortly after he learned of the discovery of these rocky worlds around a star called TRAPPIST-1 and got the assignment to visualize them. The planets had been revealed by NASA’s Spitzer Space Telescope and ground-based observatories.
“I just stopped dead in my tracks, and I just stared at it,” Hurt said in an interview. “I was imagining that could be, not our moon, but the next planet over – what it would be like to be in a system where you could look up and see continental features on the next planet.”
So began a kind of inspirational avalanche. Hurt and his colleague, multimedia producer Tim Pyle, developed a series of arresting, photorealistic images of what the new system’s tightly packed planets might look like — so tightly packed that they would loom large in each other’s skies. Their visions of the TRAPPIST-1 system would appear in leading news outlets around the world.
Artists like Hurt and Pyle, who render vibrant visualizations based on data from Spitzer and other missions, are hybrids of sorts, blending expertise in both science and art. From squiggles on charts and columns of numbers, they conjure red, blue and green worlds, with half-frozen oceans or bubbling lava. Or they transport us to the surface of a world with a red-orange sun fixed in place, and a sky full of planetary companions.
“For the public, the value of this is not just giving them a picture of something somebody made up,” said Douglas Hudgins, a program scientist for the Exoplanet Exploration Program at NASA Headquarters in Washington. “These are real, educated guesses of how something might look to human beings. An image is worth a thousand words.”
This artist’s concept by Tim Pyle allows us to imagine what it would be like to stand on the surface of the exoplanet TRAPPIST-1f, located in the TRAPPIST-1 system in the constellation Aquarius. Credits: NASA/JPL-Caltech. Full image and caption
Hurt says he and Pyle are building on the work of artistic pioneers.
“There’s actually a long history and tradition for space art and science-based illustration,” he said. “If you trace its roots back to the artist Chesley Bonestell (famous in the 1950s and ’60s), he really was the artist who got this idea: Let’s go and imagine what the planets in our solar system might actually look like if you were, say, on Jupiter’s moon, Io. How big would Jupiter appear in the sky, and what angle would we be viewing it from?”
To begin work on their visualizations, Hurt divided up the seven TRAPPIST-1 planets with Pyle, who shares an office with him at Caltech’s IPAC center in Pasadena, California.
This illustration shows one possible scenario for the hot, rocky exoplanet called 55 Cancri e, which is nearly two times as wide as Earth. Robert Hurt created this in 2016. Credits: NASA/JPL-Caltech. Full image and caption
Hurt holds a Ph.D. in astrophysics, and has worked at the center since he was a post-doctoral researcher in 1996 – when astronomical art was just his hobby.
“They created a job for me,” he said.
Pyle, whose background is in Hollywood special effects, joined Hurt in 2004.
NASA’s Kepler mission discovered a world where two suns set over the horizon instead of just one, called Kepler-16b. Robert Hurt did this illustration of this fascinating world. Credits: NASA/JPL-Caltech. Full image and caption
Hurt turns to Pyle for artistic inspiration, while Pyle relies on Hurt to check his science.
“Robert and I have our desks right next to each other, so we’re constantly giving each other feedback,” Pyle said. “We’re each upping each other’s game, I think.”
The TRAPPIST-1 worlds offered both of them a unique challenge. The two already had a reputation for illustrating many exoplanets – planets around stars beyond our own — but never seven Earth-sized worlds in a single system. The planets cluster so close to their star that a “year” on each of them — the time they take to complete a single orbit — can be numbered in Earth days.
And like the overwhelming majority of the thousands of exoplants found in our galaxy so far, they were detected using indirect means. No telescope exists today that is powerful enough to photograph them.
This artist’s concept by Tim Pyle shows what the weather might look like on cool star-like bodies known as brown dwarfs. Credits: NASA/JPL-Caltech/University of Western Ontario/Stony Brook University. Full image and caption
Real science informed their artistic vision. Using data from the telescopes that reveal each planet’s diameter as well as its “weight,” or mass, and known stellar physics to determine the amount of light each planet would receive, the artists went to work.
Both consulted closely with the planets’ discovery team as they planned for a NASA announcement to coincide with a report in the journal Nature.
“When we’re doing these artist’s concepts, we’re never saying, ‘This is what these planets actually look like,’” Pyle said. “We’re doing plausible illustrations of what they could look like, based on what we know so far. Having this wide range of seven planets actually let us illustrate almost the whole breadth of what would be plausible. This was going to be this incredible interstellar laboratory for what could happen on an Earth-sized planet.”
For TRAPPIST-1b, Pyle took Jupiter’s volcanic moon, Io, as an inspiration, based on suggestions from the science team. For the outermost world, TRAPPIST-1h, he chose two other Jovian moons, the ice-encased Ganymede and Europa.
This artist’s concept shows planet KELT-9b orbiting its host star, KELT-9. It is the hottest gas giant planet discovered so far. Credits: NASA/JPL-Caltech. Full image and caption
After talking to the scientists, Hurt portrayed TRAPPIST-1c as dry and rocky. But because all seven planets are probably tidally locked, forever presenting one face to their star and the other to the cosmos, he placed an ice cap on the dark side.
TRAPPIST-1d was one of three that fall inside the “habitable zone” of the star, or the right distance away from it to allow possible liquid water on the surface.
“The researchers told us they would like to see it portrayed as something they called an ‘eyeball world,’” Hurt said. “You have a dry, hot side that’s facing the star and an ice cap on the back side. But somewhere in between, you have (a zone) where the ice could melt and be sustained as liquid water.”
At this point, Hurt said, art intervened. The scientists rejected his first version of the planet, which showed liquid water intruding far into the “dayside” of TRAPPIST-1d. They argued that the water would most likely be found well within the planet’s dark half.
“Then I kind of pushed back, and said, ‘If it’s on the dark side, no one can look at it and understand we’re saying there’s water there,’”
Hurt said. They struck a compromise: more water toward the dayside than the science team might expect, but a better visual representation of the science.
This artist’s concept by Tim Pyle depicts Kepler-186f, the first validated Earth-size planet to orbit a distant star in the habitable zone — a range of distance from a star where liquid water might pool on the planet’s surface. Credits: NASA/Ames/SETI Institute/JPL-Caltech. Full image and caption
The same push and pull between science and art extends to other forms of astronomical visualization, whether it’s a Valentine’s Day cartoon of a star pulsing like a heart in time with its planet, or materials for the blockbuster announcement of the first detection of gravitational waves by the Laser Interferometer Gravitational-Wave Observatory in February 2016. They’ve also illustrated asteroids, neutron stars, pulsars and brown dwarfs.
Visualizations based on data can also inform science, leading to genuine scientific insights. The scientists’ conclusions about TRAPPIST-1 at first seemed to suggest the planets would be bathed in red light, potentially obscuring features like blue-hued bodies of water.
“It makes it hard to really differentiate what is going on,” Hurt said.
Hurt decided to investigate. A colleague provided him with a spectrum of a red dwarf star similar to TRAPPIST-1. He overlaid that with the “responsivity curves” of the human eye, and found that most of the scientists’ “red” came from infrared light, invisible to human eyes. Subtract that, and what is left is a more reddish-orange hue that we might see standing on the surface of a TRAPPIST-1 world — “kind of the same color you would expect to get from a low-wattage light bulb,” Hurt said. “And the scientists looked at that and said, ‘Oh, ok, great, it’s orange.’ When the math tells you the answer, there really isn’t a lot to argue about.”
For Hurt, the real goal of scientific illustration is to excite the public, engage them in the science, and provide a snapshot of scientific knowledge.
“If you look at the whole history of space art, reaching back many, many decades, you will find you have a visual record,” he said. “The art is a historical record of our changing understanding of the universe. It becomes a part of the story, and a part of the research, I think.”
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In the BBC six o’clock news of 15 July 2015, as a result of the first New Horizons images, several paintings of Pluto were shown (some by myself) with the statement, ‘There is no longer any need for artists’ impressions.’ This comment was of course intended to be whimsical but, as the public sees it, there is an element of truth in it. We have after all now received images from all of the major bodies in our Solar System.
There will always be a need for artists (quite apart from the aesthetic aspects; space art can be at least as beautiful as terrestrial art) because from space probes we only see the whole object – planet, moon, comet – or close-ups of it, as it looks from space. Only artists can visualise what it would look like for someone actually standing on the surface. Of course, we heard the same sort of comments when photography was invented, when digital art became available, when the Hubble Space Telescope sent back its first amazing images of distant stars and nebulae. . . But let’s take a look at the history and background of space art.
… there was a more unusual item on Mr. Pesquet’s agenda. Working with the earthbound artist Eduardo Kac, he created an artwork in space. It was a simple piece: nothing more than could be done with two sheets of paper and a pair of scissors. “Since the goal was to be born in space, it had to be created with materials that were already in the space station,” Mr. Kac (pronounced katz) explained in a telephone interview from his home in suburban Oak Park, Ill. Transporting art materials by rocket ship was not in the plan.
“Inner Telescope” floats in the ISS Cupola.
The artwork — a piece of paper cut into an M, and another piece of paper rolled into a tube and stuck through the middle of the M — might look a bit silly on Earth, where gravity would accentuate its flimsiness. But floating weightlessly in the space station, it looks fragile, even magical — not unlike the planet beyond.
Viewed with a certain amount of imagination, the paper construction can be said to spell “moi.” Mr. Kac, a professor of art and technology at the School of the Art Institute of Chicago, means this not as an individual “me” but in the collective sense: His “moi” stands for all of us. The piece itself is called “Inner Telescope,” for reasons that become clear only when you look through the O formed by the paper tube and view a tiny portion of Earth. “We point a telescope to the stars,” he said. “But this is a telescope that from the stars we point to ourselves.”
Here is a video about the project. (It is in French but you can obtain rough translated captions via Settings -> Subtitles/CC -> Language selection. Then click on the CC control.)
Humankind has practiced outer space—that is, we have performed it—since time immemorial. Through science, philosophy and the arts, we have practiced extraterrestrial culture since the first time we took a star as a reference to life on Earth—Ptolemy, Copernicus and Galileo were all already practicing extraterrestrial culture. However, today extraterrestrial culture acquires a much more material potential. In an age of climate change and orbital trash, of planetary stewardship and satellite telecommunication, of interplanetary colonialism and orbital cosmopolitanism, the performativity of our extraterrestrial culture is no longer exclusively a projection for the future, but rather the pressing expression of the material relationality between us, our planet, and with the universe at large. How we enact space now is therefore a determinant factor in the ways in which we will continue to practice space in the future.
And how would he like to express extraterrestrial space?
Myself? I want to stage Waiting for Godot in orbit, and have Neil deGrasse Tyson and Bill Nye play Vladimir and Estragon. The play is a seminal work in the history of theatre in general, and an exemplary case of a genre called “theatre of the absurd.” This particular genre’s main characteristics are that the storyline is often circular and the characters live through a cyclical, almost nonsensical existence. In Waiting for Godot, Vladimir and Estragon spend the entire play waiting for Godot, whose complete identity we never really learn and who actually never shows up. The play has often been interpreted as a poetic representation of humans’ existential agony, and the search for a meaning in a world that may not have one at all. The end of the play encapsulates this:
Estragon (Neil): Well? Shall we go?
Vladimir (Bill): Yes, let’s go.
They don’t move.
Imagine Neil deGrasse Tyson and Bill Nye playing these characters and saying these lines…in orbit…on board the ISS…wouldn’t that be something?
