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Comet Tsuchinshan-ATLAS is now visible in the early morning sky.

Why is it important to search for exoplanets in triple star systems and how many can we find there? This is what a recent study accepted by Astrophysics & Space Science hopes to address as a pair of researchers from the University of Texas at Arlington investigated the statistical likelihood of triple star systems hosting exoplanets. This study holds the potential to help researchers better understand the formation and evolution of triple star systems and whether they are suitable to find life as we know it.

Here, Universe Today discusses this incredible research with Dr. Manfred Cuntz, who is a physics professor at the University of Texas at Arlington and lead author of the study, regarding the motivation behind the study, the most significant results, the importance of studying triple star systems, and the likelihood of finding exolife in triple star systems. Therefore, what was the motivation behind the study?

Dr. Cuntz tells Universe Today, “Ages and metallicity (i.e., the amount of heavy elements = elements other than hydrogen and helium) are fundamental properties of stars – a statement that applies to all stars. Considering that most stars (which however does not apply to the sun) are members of higher order systems – the study of stars in triple stellar systems is a natural extension of research focusing on single stars.”

For the study, the researchers conducted a statistical analysis regarding both the ages and metallicities of triple star systems with a total of 27 confirmed exoplanets based on past research, with the number of exoplanets in each system ranging from 1 to 5. The ages of the triple star system ages, with margins of error, ranged between 20 million years old to 7.2 billion years old. For context, our Sun is estimated to be slightly more than 4.6 billion years old.

The metallicities of the star systems, with margins of error, ranged between -0.59 to +0.56, which is often calculated based on the ratio of iron to hydrogen (Fe/H), and is also calculated with the equation X + Y + Z =1, with X being the fraction of hydrogen, Y being the fraction of helium, and Z being everything else (i.e., carbon, oxygen, silicon, iron, etc.). These values range between -4.5 to +1.0, with stars exhibiting 0, -1, greater than 0, and less than 0 indicating a star is equal in iron abundance to our Sun, one-tenth the iron abundance of our Sun, greater metal content than our Sun, and less metal content than our Sun, respectively. Therefore, what were the most significant results from this study?

“Two highly significant results have been identified,” Dr. Cuntz tells Universe Today. “First, stars in triple stellar systems are on average notably younger than stars situated in the solar neighborhood. The most plausible explanation is a possible double selection effect due to the relatively high mass of planet-hosting stars of those systems (which spend less time on the main-sequence than low-mass stars) and that planets in triple stellar systems may be long-term orbitally unstable. The stellar metallicities of those stars are on average solar-like; however, owing to the limited number of data, this result is not inconsistent with the previous finding that stars with planets tend to be metal-rich as the deduced metallicity distribution is relatively broad.”

The distances to the respective triple star systems range between 4.3 to 1,870 light-years from Earth, but only 6 of the 27 triple star systems reside within 100 light-years away. These six triple star systems include Alpha Centauri (4.3 light-years), Epsilon Indi (11.9 light-years), LTT 1445 (22.4 light-years), Gliese 667 (23.6 light-years), 94 Ceti (73.6 light-years), and Psi1 Draconis (74.5 light-years), with the number of total exoplanets (with exoplanet candidates) within each system being 3 (2), 1, 1, 2 (1), 1, and 1, respectively. For context, as of September 2024, the total number of confirmed exoplanetary systems within our cosmos is more than 4,300 that encompasses almost 5,800 exoplanets. But despite the small number of triple star systems that host exoplanets, what is the importance of studying triple star systems?

Dr. Cuntz tells Universe Today, “Most stars (which however does not apply to the sun) are members of higher order systems, especially binaries – and in less common cases triple stellar systems, and systems of even higher order. Therefore, the study of planets hosted by triple stellar systems is a natural extension of the standard approach focusing on planets around single stars. The current study focuses on some of the properties of stars in triple stellar systems, which are also known to host (a) planet(s) – a relatively rare setting. The importance of the current study is to expand our general understanding of star-planet systems.”

For Alpha Centauri, the exoplanet, Proxima Centauri b, has been confirmed to be terrestrial (rocky), approximately the size of Earth in both radius and mass, and orbits within the habitable zone (HZ) of Proxima Centauri, one of the stars that comprise the Alpha Centauri triple star system. The only other terrestrial exoplanet orbiting within its star’s HZ is Gliese 667 Cc, whose mass and radius is larger than the Earth, designating it as a super-Earth. Therefore, given the small number of triple star systems that have exoplanets and even fewer that host terrestrial exoplanets orbiting in its HZ, what is the likelihood of finding exolife in triple star systems?

“The only planet where we know for sure that life does exist is Earth,” Dr. Cuntz tells Universe Today. “However, through both observational and theoretical studies during many decades of committed work, scientists are convinced that exolife is almost certainly real. This statement should also apply to planets in triple star systems. However, those planets are typically subject to relatively variable environmental forcings (e.g., variable amounts of radiation received by the stellar components), which is expected to reduce the likelihood of advanced life forms, but should still permit microbial life, especially extremophiles.”

As the number of confirmed exoplanets continues to grow, so should the confirmed number of triple star systems that host exoplanets, as well. When science fiction fans read about multi-star systems, they almost immediately think of the iconic scene in Star Wars: A New Hope of Luke Skywalker watching two stars setting on the horizon. While Tatooine was habitable for humans and other interesting life forms, this might not be the case in the real world, as demonstrated by Proxima Centauri b currently being the only Earth-like exoplanet orbiting in its HZ within 100 light-years from Earth. Therefore, what constraints should scientists put on finding life in triple star systems? Should we instead study their moons, as the film Avatar depicted the semi-habitable moon, Pandora, orbiting a much larger exoplanet within the Alpha Centauri system? Are triple star systems with exoplanets as rare as the statistics show today?

“The search for life outside of planet Earth continues to be a fascinating topic,” Dr. Cuntz tells Universe Today. “Political and societal support for ongoing and future space missions is highly appreciated. We, as scientists, are grateful about the ongoing support by the taxpayers around the world, but especially here in the U.S.”

What new discoveries about triple star systems will researchers make in the coming years and decades? Only time will tell, and this is why we science!

As always, keep doing science & keep looking up!

Reference: Cuntz, Manfred & Patel, Shaan D. “On the Age and Metallicity of Planet-hosting Triple Star Systems.” Astrophysics and Space Science (2024) (accepted)

The post We Don’t See Many Planets in Old Triple Star Systems appeared first on Universe Today.

The U.S. Federal Aviation Administration is requiring an investigation of the anomaly a SpaceX Falcon 9 rocket experienced during the Crew-9 astronaut launch on Sept. 28.

China has revealed the design of its moonwalking spacesuit, which the nation hopes to start putting to use on the lunar surface by 2030.

NASA has selected Intuitive Machines of Houston and Aalyria Technologies Inc. of Livermore, California, to perform capability studies with the goal of advancing space communications and exploration technologies. These studies will allow NASA to gain insights into industry capabilities and innovations to facilitate NASA partnerships with commercial communications and navigation providers.

The awards, under the Next Space Technologies for Exploration Partnerships-2 (Next STEP-2) Broad Agency Announcement (BAA) Appendix Q, are firm fixed-price milestone-based contracts.

Intuitive Machines is awarded $647,600 — Study Area No. 1, Lunar User Terminals and Network Orchestration — to conduct state-of-the-art studies and demonstrations for a dual-purpose navigation and communication lunar surface user terminal. The terminal will support lunar surface exploration planning and ensure interoperability with future LunaNet compatible service providers working in partnership with NASA, ESA (European Space Agency), and other space agencies.

Aalyria Technologies is awarded $393,004 — Study Area No. 2, Network Orchestration and Management System (NOMS) — to provide NASA with insights on advanced Network Orchestration and Management Systems that effectively address NASA’s need to integrate into multiple commercial and government communication service providers supporting the Near Space Network.

NASA’s Near Space Network is managed by the agency’s Goddard Space Flight Center in Greenbelt, Maryland, under the direction of the agency’s SCaN (Space Communications and Navigation) program office within the Space Operations Mission Directorate at NASA Headquarters in Washington. The Near Space Network provides NASA missions with robust communications services through an interoperable architecture composed of a mixture of existing NASA and commercial services.

“These awards are part of NASA’s continuing effort to build commercial partnerships to help support increasingly sophisticated and high-demand space missions,” said Greg Heckler, new capability lead for the SCaN Program at NASA Headquarters in Washington. “Seamless interoperability across networks, from here on Earth to cislunar space, is an essential element of SCaN’s emerging ‘one network’ approach. These awards will move us one step closer to realizing that future.”

The innovative studies delivered by industry through the Next Space Technologies for Exploration (NextSTEP) – 2 Omnibus Broad Agency Announcement vehicle bolster the agency’s goal to create a reliable, robust, and cost-effective set of commercial services in which NASA is one of many customers.

Learn more about the NextSTEP public-private partnership model at:

https://www.nasa.gov/nextstep

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Jeremy Eggers
Goddard Space Flight Center, Greenbelt, Md.
757-824-2958
jeremy.l.eggers@nasa.gov

To shape NASA’s path of exploration forward, Dr. Gioia Rau unravels stars and worlds beyond our solar system.

Name: Dr. Gioia Rau
Title: Astrophysicist
Organization: Exoplanets and Stellar Astrophysics Laboratory, Astrophysics Division, Science Mission Directorate (Code 667)

Dr. Gioia Rau is an astrophysicist at NASA’s Goddard Space Flight Center in Greenbelt, Md.Photo courtesy of Gioia Rau

What do you do and what is most interesting about your role here at Goddard?

I’m an astrophysicist who studies both evolved stars, stars that about to die, and exoplanets, planets outside our solar system. I study the stars that once held the elements that are in our body, such as calcium. I also lead the science part of several mission concept studies. And I am really passionate about strategic thinking.

How does it feel to achieve your childhood dream of becoming an astrophysicist at NASA?

I am from Italy. Growing up, I was always fascinated by NASA. As a child, I watched the shuttle launches. I loved everything about stars, planets, and galaxies. I devoured astronomy books. I always knew that I wanted to study astrophysics.

Around 10 years old, I wrote a letter to NASA saying that I wanted to become an astrophysicist to study the universe. NASA sent me information and encouraged me to study and work hard. So I did.

I still remember my first day working at NASA. I looked around with so much joy at my dream coming true. Every day that I work at Goddard, I find more passion to continue pursue my dreams.

What is your educational background?

In 2009, I earned a Bachelor of Science in physics from the University of Rome, La Sapienza. In 2011, I obtained a master’s in physics and astrophysics there. Also in 2011, I was awarded a very competitive fellowship to do a master’s thesis at the California Institute of Technology and NASA’s Jet Propulsion Lab thanks to my high GPA. In 2016, I earned a Ph.D. in astrophysics from the University of Vienna. I came to Goddard in 2017 when I obtained a NASA post-doctoral fellowship.

Why do you study evolved stars? 

Evolved stars are the future of our own Sun, which in about 5 billion years will die. Evolved stars also produce elements found in our own bodies, as, for example, the calcium in our bones, the iron in our blood, and the gold in our rings. The stardust that I study is spread by the stellar winds into the interstellar medium to form new generation of stars and planets, and contribute to the cosmic recycle of matter in the universe.

As Carl Sagan said, “We are all made of stardust.”

What is most interesting about studying exoplanets?

If we discover an exoplanet within the habitable zone of its star, we increase the likelihood of finding a planet with Earth-like conditions. This can enhance our understanding of planetary formation processes, and help determine if these exoplanets may harbor life through studying their atmospheres.

My team of students and scientists used Artificial Intelligence techniques to discover new exoplanet candidates. They are called candidates because they need to be confirmed through follow-up observations. It was a very exciting, pioneering project using cutting-edge techniques.

Why is working on mission concepts important to you?

Mission concepts represent the future of space exploration, and I lead the science team of multiple mission concepts. By working on these pioneering projects, we as teams are actively shaping the future of NASA, and advancing the field of astrophysics. I am grateful for the opportunity to collaborate with so many brilliant scientists and engineers. I am passionate about strategic thinking and the visionary process behind it to shape the future of science and of organizations alike. I thrive on seeing the big picture and contributing to initiative that shape the future of organizations and people alike.

Why do you love mentoring?

I love working with students. It is gratifying to teach them and fuel their passions and also, again, working with the next generation helps shape NASA’s future. I tell the students what I firmly believe: that resilience, grit, passion, and hard work are some of the most important qualities in a scientist. That integrity, humility, and flexibility are great values to honor as a scientist. And I tell them not to be afraid of trying something new. After all, failure is part of being a scientist. Doing science is about learning from failures, to be successful. As scientists, we follow the scientific method to test our hypotheses through experiments. Ninety-nine percent of the time that experiment does not work the first time. So we need to keep refining the experiment until it does work. I also tell my students to keep in focus their goal, and work very hard toward it: make a plan and stick to it.

What is your message when you do outreach?

I started doing outreach when I was in college. I have since done hundreds of outreach events; I am passionate about sharing the joy of astrophysics, and my passion for it, with the general public! When I do outreach, my goal is to make the Universe accessible to the public: the Cosmos belongs to all of us, and we can all enjoy the beauty and wanders of the Universe, together.  I aim to build connections that bridge the gap between science and the public, working together to deepen our understanding of the Universe and inspire the next generation of scientists. I also remind the audience that behind every success there are a multitude of failures that led to that success. I tell them why I am passionate about science and how I became an astrophysicist at NASA. Engaging with people makes science more accessible and relatable. Outreach inspires the next generation to become scientists.

Who is your science hero?

Hypatia. She was an astronomer and a philosopher who lived in ancient Greece. At that time, scientists were also philosophers, and I love philosophy. She was martyred because her views were considered to be against the established way of thinking. She was a martyr for freedom of thought.

Do you have a phrase that you live by?

Keep on dreaming, and work hard toward your goals; ad astra per aspera!

Who do you wish to thank?

My father and my mother, and my current family: my husband who is my biggest supporter and fan, and my kids for the joy they bring. I also would like to thank all my mentors along the way. They always believed in me and guided me on my path.

What do you do for fun?

I love playing volleyball, skiing, reading, taking photos, playing the piano and the guitar, hiking, sailing, baking, and of course being with my family.

What is your “six-word memoir”? A six-word memoir describes something in just six words.

Unraveling mysteries, shaping futures, inspiring paths.

Conversations With Goddard is a collection of Q&A profiles highlighting the breadth and depth of NASA’s Goddard Space Flight Center’s talented and diverse workforce. The Conversations have been published twice a month on average since May 2011. Read past editions on Goddard’s “Our People” webpage.

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Details Last Updated Oct 01, 2024 EditorMadison OlsonContactRob Garnerrob.garner@nasa.govLocationGoddard Space Flight Center Related Terms

• People of Goddard
• Goddard Space Flight Center
• People of NASA

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NASA astronaut Josh Cassada holds a roll-out solar array as he rides the Canadarm2 robotic arm during a spacewalk in support of the Expedition 68 mission aboard the International Space Station on Dec. 3, 2022. Credit: NASA

Three-time Spacewalker Josh Cassada to Retire from NASA

NASA astronaut Josh Cassada retired Oct. 1, after 11 years of service to the agency across multiple programs, including 157 days in space and three spacewalks. Cassada also is a retired United States Navy captain and naval aviator with more than two decades of service.

Cassada served as pilot of NASA’s SpaceX Crew-5 mission and Expedition 68 flight engineer aboard the International Space Station, executing myriad maintenance, contingency, and upgrade activities inside the station while also contributing to hundreds of experiments and technology demonstrations. His three spacewalks outside of the orbiting laboratory totaled more than 21 hours, successfully installing a pair of International Space Station Roll-Out Solar Arrays (IROSAs) to boost the station’s electrical capacity. Cassada, alongside crewmate NASA astronaut Frank Rubio, also assembled the infrastructure for a future IROSA installation and fully restored a malfunctioning legacy solar array.

“I want to extend my sincere gratitude to Josh for his dedication and service to human space exploration,” said NASA Johnson Space Center Director Vanessa Wyche. “Josh’s contributions and achievements to the advancement of science and exploration will inspire the next generation of explorers, the Artemis generation, and benefit humanity for decades to come.”

NASA astronaut Josh Cassada poses for a portrait in his extravehicular mobility unit spacesuit on August 8, 2022. Credit: NASA/Robert Markowitz

Throughout Expedition 68, Cassada and his crewmates completed extensive problem-solving with ground teams, including the modification of the SpaceX Dragon spacecraft to accommodate an additional crew member in the event of an emergency return, and leveraged the crew’s various skill sets and training to ensure continued safe and effective operations for current and future crews.

In Houston, Cassada served as a capsule communicator in NASA’s Mission Control Center and assistant to the chief of the Astronaut Office for space station operations. As a physicist and test pilot, Cassada also contributed to the development of NASA’s Commercial Crew Program and Orion spacecraft and represented the Astronaut Office in technical and operational reviews of scientific experiments such as the Alpha Magnetic Spectrometer and Cold Atom Lab.

“Josh has played a significant role in NASA’s deliverance of reliable and cost-effective human transportation to and from the space station,” said Norm Knight, director of flight operations at NASA Johnson. “Through his dedication and commitment to human spaceflight exploration, Josh’s work will continue to push us forward on our journey back to the Moon, and beyond. We will miss him and are excited to see what his next journey entails.”

As he transitions from government service, Cassada will return to the private sector, working on extremely low light detection technologies with broad and emerging applications in various areas, including quantum networks and computing, remote sensing, long-range communication, semiconductor manufacturing, and medical imaging.

“I am incredibly grateful for my many opportunities here at NASA,” Cassada said, “and especially to have served alongside some of the most amazing people both on and off our planet, accomplishing things that are only possible when we work and innovate together as a team.  As humans, we explore . And each scientific adventure, whether in a lab on Earth or in space, requires courage to explore and advance society. I am incredibly fortunate to have been surrounded by explorers during my entire career so far and going forward. An expedition may seem daunting, but it’s a lot less so when you’re prepared and with the right crewmates.”

Before his selection by NASA in 2013 as a member of NASA’s 21st Class, Cassada earned his doctorate in High Energy Particle Physics from the University of Rochester, New York and was a U.S. Navy pilot, instructor pilot, test pilot, and instructor test pilot. Throughout his career, Cassada has accumulated more than 4,000 flight hours in over 50 different aircraft and has been awarded various military and civilian awards.

Cassada graduated from White Bear Lake Area High School in Minnesota in 1991 and received his bachelor’s in Physics in 1995 from Albion College in Michigan.

Learn more about International Space Station research and operations at:

https://www.nasa.gov/station

-end-

Courtney Beasley
Johnson Space Center, Houston
281-483-5111
courtney.m.beasley@nasa.gov

Using the James Webb Space Telescope, astronomers have discovered carbon dioxide and hydrogen peroxide at the surface of Pluto's largest moon, Charon, potentially shedding light on its origins.