Ballooning to the Stars: PICTURE-C Mission Sets Stage for Exoplanet Exploration from the Edge of Space
NASA concept art.
06/09/2023
By Edwin L. Aguirre
On Valentine's Day 1990, as NASA鈥檚 Voyager 1 spacecraft was leaving our solar system, mission controllers commanded the unmanned probe to turn its camera toward Earth and take one last shot before embarking on its long interstellar journey.聽
Voyager captured a portrait of Earth from four billion miles away, appearing like a tiny, dim point of light floating amid the vast emptiness of space. That view inspired the late astronomer Carl Sagan to publish his 1994 book, entitled 鈥淧ale Blue Dot,鈥 which detailed his vision of humanity鈥檚 future in space.聽
Since then, astronomers worldwide have used advanced ground-based telescopes and orbiting observatories like Kepler, TESS, Hubble and the James Webb Space Telescope to examine the sky for other potential 鈥減ale blue dots鈥濃擡arth-like planets, orbiting nearby sun-like stars, that are capable of harboring life. To date, more than 5,000 confirmed exoplanets have been found in nearly 4,000 stellar systems scattered across our cosmic neighborhood. Of these, more than 50 are considered to be Earth-like.聽
Among the scientists involved in this field of exoplanet research is Asst. Research Prof. Christopher Mendillo of the university's Lowell Center for Space Science and Technology (LoCSST). Last fall, Mendillo, along with Physics Prof. and LoCSST Director Supriya Chakrabarti and the project鈥檚 research team, successfully launched a planet-seeking telescope to the edge of the atmosphere from a NASA facility in Fort Sumner, New Mexico.
Called PICTURE-C, which stands for Planetary Imaging Concept Testbed Using a Recoverable Experiment鈥擟oronagraph, the 14-foot-long, 1,500-pound telescope was carried to the stratosphere by an unmanned, helium-filled balloon 400 feet wide and several stories high that was released from the Columbia Scientific Balloon Facility in Texas on Sept. 28.聽
Mendillo says balloons are well-suited to search for planets outside our solar system.聽
鈥淲e鈥檝e used sounding rockets before, but balloons are an amazing platform to use for exoplanet research because of their relatively low cost, ability to lift heavy payloads and long observing duration,鈥 he says.聽
PICTURE-C was designed, built and tested by a team of student and faculty researchers and engineers at the LoCSST lab facility with support from a $5.6 million grant from NASA. The project鈥檚 goal is to detect debris disks, interplanetary dust and, possibly, exoplanets around nearby stars.聽
NASA recently awarded Mendillo a five-year, $7 million grant to develop the next generation of UML鈥檚 high-flying telescope, which will be dubbed PICTURE-D (Planetary Imaging Coronagraph Testbed Using a Recoverable Experiment for Debris Disks).聽
鈥淭he grant will help bring our research group to a new level.鈥 -Prof. Christopher MendilloNASA has also named Mendillo a Nancy Grace Roman Technology Fellow, an award that gives early career researchers the opportunity to develop innovative technologies while honing the skills needed to lead wastrophysics flight instrumentation development projects. He will receive $500,000 in funding as part of the fellowship program.
鈥淭he grant will help bring our research group to a new level,鈥 Mendillo says, adding that it gives LoCSST the opportunity to add facilities or equipment to its lab and possibly to hire personnel.聽
To the Threshold of Space聽
The data gleaned from the PICTURE-C mission will not only help find new planets, but it will also shed light on the evolution of our solar system, says Chakrabarti, who is PICTURE-C鈥檚 principal investigator.聽
鈥淥ur balloon missions will enable us to gain a better understanding of the processes and dynamics that formed our own solar system,鈥 he says.聽
PICTURE-C spent 14 hours observing nearby stars at an altitude of 127,000 feet鈥 roughly 3陆 times higher than the typical cruising altitude of a passenger jetliner鈥攖o get above 99% of the Earth鈥檚 atmosphere.聽
鈥淎tmospheric turbulence distorts and blurs our image of the stars,鈥 notes Chakrabarti.聽
After successfully completing its observations, ground controllers sent a command to release PICTURE-C from the balloon. They then deployed a parachute to slow down the telescope and allow it to land gently on the desert floor for reuse in a future mission.聽
The primary stellar targets selected for this mission were Vega (Alpha Lyrae), which is one of the brightest stars in the sky, and Epsilon Eridani.聽
鈥淒ust had been detected around Vega, so it鈥檚 thought to have a very big and bright debris disk close to the star. It鈥檚 never been imaged directly in visible light, never been resolved,鈥 says Mendillo. 鈥淓psilon Eridani, which is also fairly bright, is believed to have a Jupiter-sized exoplanet orbiting the star, but no one has seen the planet yet.鈥澛
In the coming months, UML scientists will analyze the data that PICTURE-C captured and publish the results.
鈥楲ike Looking for a Marble Next to a Lighthouse Beacon鈥櫬
鈥淭hat was also a big success, including the recovery,鈥 notes Chakrabarti.聽
The latest mission further validated many key technologies developed at LoCSST that are essential for the first direct imaging of exoplanets from a balloon.聽
PICTURE-C featured a specialized optical imaging system, called a 鈥渧ector vortex coronagraph,鈥 which was coupled to a telescope with a primary mirror 24 inches in diameter. The coronagraph was designed to 鈥渕ask,鈥 or greatly suppress, 99.99% of the direct light coming from the host star so that small, faint objects very close to the star鈥 such as planets or interplanetary dust that otherwise would be hidden in the star鈥檚 bright glare鈥攃ould be studied in great detail.聽
鈥淭his is important, since we鈥檙e trying to see planets that are more than a billion times dimmer than their host star,鈥 Chakrabarti explains. 鈥淚t鈥檚 like looking for a marble next to a lighthouse beacon.鈥 To obtain the highest image quality possible, the coronagraph used an onboard active optical pointing control system and adaptive optics designed and built by Mendillo and Postdoctoral Research Associate Kuravi Hewawasam 鈥20. It used a deformable mirror that could change its shape at high speed and in real time, according to the wavefront of the starlight that was coming in.
鈥淭his control system could optically stabilize the light beam coming from the telescope and keep the coronagraph centered on the target star to an accuracy of one milliarcsecond, or better, throughout the camera鈥檚 exposure,鈥 says Mendillo.聽
鈥淎 milliarcsecond is equivalent to resolving an object approximately 2 meters wide on the surface of the moon, which is about 385,000 kilometers away.鈥澛
Mendillo notes that the pointing stability they achieved had never been accomplished before from any platform, especially hanging from a balloon. 鈥淚t performed better than the Hubble Space Telescope and the James Webb Space Telescope,鈥 he says.聽
At this level of sensitivity and precision, maintaining the telescope鈥檚 ultrasharp focus and pointing are critical to the mission, since the telescope鈥檚 performance determines how many exoplanets the researchers are able to detect.聽
According to Mendillo, PICTURE-C was able to use its deformable mirror to create the first-ever high-contrast coronagraph image produced by an observatory not attached to the surface of the Earth.聽
鈥淭his was a huge step toward our ultimate goal of directly imaging and characterizing Earth-like exoplanets from a balloon,鈥 he says.
PICTURE-D: The Next Generation聽
For the PICTURE-D project, the researchers will use the same balloon platform and same telescope, but are making several major upgrades to the coronagraph to improve its performance, according to Mendillo.聽
Currently, Mendillo says, they can only search one side of a star at a time. Adding a second deformable mirror will allow them to look around the entire star at the same time at extremely high contrast.聽
鈥淲e鈥檙e also collaborating with our partners at Leiden Observatory in the Netherlands and NASA鈥檚 Ames Research Center in integrating a new type of coronagraph that will allow us to make polarization measurements of debris disks, as well as look for planets around binary star systems,鈥 he says.聽
If everything goes well, the team hopes the next mission will be the actual science flight, with the telescope fulfilling the project鈥檚 science objectives.聽
Chakrabarti says the team鈥檚 approach to research is unique.聽
鈥淲e鈥檙e a small group. Everybody does everything,鈥 he says. 鈥淭his is the only group in the entire world who has been flying instruments in near-space to validate all these technologies. That鈥檚 our contribution to the field.鈥澛
In addition to Mendillo, Chakrabartiand Hewawasam, the team members include senior mechanical engineer Jason Martel, Ph.D. students Sunip Mukherjee and Thaddeus Potter, and Physics Assoc. Prof. Timothy Cook, who is the project鈥檚 co-investigator, along with other collaborators, including scientists from NASA鈥檚 Jet Propulsion Laboratory and Goddard Space Flight Center.聽
鈥淧ICTURE-D will be the fourth iteration of the PICTURE family of missions, which began developing spaceflight exoplanet imaging technologies back in 2005,鈥 says Mendillo.聽
鈥淭hese missions are steppingstones along the path to an experiment that will one day take the first picture of a new pale blue dot鈥 an Earth-like exoplanet circling a distant star.鈥