A Super-Tiny Star Gave Birth to a Giant Planet And We Don't Know How
Such small stars were thought to be incapable of producing giant planets. But there, in its orbit, appears to be unmistakable evidence of an absolute unit: a gas giant around the size of Saturn.
TOI-6894b, as the exoplanet is named, has 86 percent of the radius of Jupiter. At just 23 percent of the radius and 21 percent of the mass of the Sun, its parent TOI-6894 is the smallest star yet around which a giant world has been found.
"I was very excited by this discovery," says astrophysicist Edward Bryant of the University of Warwick in the UK, who led the large international research team.
"We did not expect planets like TOI-6894b to be able to form around stars this low-mass. This discovery will be a cornerstone for understanding the extremes of giant planet formation."
Planets are born from the material that's left over from the formation processes of its host star. Stars form when a dense clump of material in a cloud of gas and dust collapses under gravity. Material from that cloud spools around the spinning protostar in a disk that feeds the star's growth; when the star is large enough to push the material away with its stellar wind, growth stops.
The remaining material is what makes planets. The dust clumps together, gradually building worlds that end up orbiting the star.
Here's the thing, though. The amount of material in the disk is thought to be proportional to the mass of the star. The reason tiny red dwarf stars shouldn't be able to make giant planets is because there just oughtn't be enough material to do so.
Nevertheless, these strange, 'impossible' systems show up from time to time, suggesting not just that giant planets can form around tiny stars, but that the process is not all that uncommon. We don't have a good handle on just how common it is, so Bryant and his team embarked on a mission to scour TESS data for clues.
"I originally searched through TESS observations of more than 91,000 low-mass red-dwarf stars looking for giant planets," he says. "Then, using observations taken with one of the world's largest telescopes, ESO's VLT, I discovered TOI-6894b, a giant planet transiting the lowest mass star known to date to host such a planet."
Exoplanets are usually found via a technique known as the transit method. When an exoplanet orbiting a star passes between us, the observers, and the star, that star's light dims minutely. Astronomers can determine the presence of an exoplanet by looking for periodic dips in the star's light. It's usually a tiny signal that takes quite a bit of analysis to find.
When the researchers looked at TOI-6894, they found its light dimming by an absolutely whopping 17 percent. According to the team's observations of the transits, that would make the diameter of the star about 320,000 kilometers (200,000 miles), while the exoplanet is around 120,000 kilometers across.
Follow-up observations to see how much this giant exoplanet's gravity affects the orbital motion of the star revealed the mass of TOI-6894b. It's just 17 percent of the mass of Jupiter, suggesting an exoplanet atmosphere that is light and fluffy.
This is exciting for a few reasons. Because the exoplanet has such deep transits, it's a perfect candidate for atmosphere study. During those transits, some of the star's light filters through the diffuse atmosphere. As it does so, it can become altered by the atoms and molecules therein, allowing scientists to literally see what TOI-6894b is made of.
A team of astronomers has already applied for time with JWST to perform these atmospheric studies. Because the exoplanet is quite cool (temperature wise, but also just in general), they expect to find a lot of methane.
"This system provides a new challenge for models of planet formation, and it offers a very interesting target for follow-up observations to characterize its atmosphere," says astrophysicist Andrés Jordán of the Millennium Institute of Astrophysics in Chile.
Hopefully, these studies will also shed some light on how TOI-6894b formed. There are two scenarios astronomers prefer for gas giants: a gradual accumulation of material from the bottom up, or the direct collapse of an instability in the protoplanetary disk.
Based on the team's observations, neither scenario quite works. More detail on the composition of TOI-6894b could help tease out which is the more likely pathway for the formation of giant worlds orbiting tiny stars.
"It's an intriguing discovery. We don't really understand how a star with so little mass can form such a massive planet!" says astrophysicist Vincent Van Eylen of University College London.
"This is one of the goals of the search for more exoplanets. By finding planetary systems different from our Solar System, we can test our models and better understand how our own Solar System formed."
The discovery has been published in Nature Astronomy.
Water Discovered Around a Young, Sun-Like Star For First Time
June's Full Moon Will Be The Lowest in The Sky For Decades. Here's Why.
The Milky Way Might Not Crash Into The Andromeda Galaxy After All
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Yahoo
26 minutes ago
- Yahoo
Inspector says school is 'so good they'd send their children there'
A PRIMARY school is celebrating after being judged "outstanding" by Ofsted, with inspectors saying they'd send their own children there. Suckley School said inspectors told them that they would have "loved" for their own children to attend the school during the inspection. The school has received a glowing report from inspectors, who said it was an "inspirational school where pupils flourish". It received the highest ranking of "outstanding" in quality of education, behaviour and attitudes, personal development and leadership and management. READ MORE: Line-up of performers confirmed for Worcester Carnival READ MORE: Warning of risk to vulnerable as heat health alert raised to amber READ MORE: 450 home plan for Droitwich already 'suffering overdevelopment' They said pupils were achieving "exceptionally" and that classrooms were a "calm and purposeful" environment. The school's support for pupils' personal development also received high praise, with inspectors drawing attention to an initiative in which Year 6 pupils carry out work experience. Inspectors were impressed by other enrichment opportunities at the school, including visiting an inner-city school in Birmingham to experience a contrasting location. One pupil said "this helps bring learning to life". Staff are also said to be "very proud" to work at the school. A spokesperson for Suckley School said: "These observations are testament to the incredible dedication of all the staff and governors at Suckley School who have worked, and continue to work, tirelessly for all of the children. "Their skills and expertise have been rightly acknowledged by the inspectors, who praised staff for the curriculum being 'implemented exceptionally well' and recognising we go 'beyond the expected'. "Our favourite comments throughout the inspection were from the lead inspector who simply said 'I'd have loved my children to have come here' and 'what you have here is gold dust'. "Ofsted also left us with no 'areas for improvement'."
Yahoo
an hour ago
- Yahoo
GitLab (GTLB) Gets Vote of Confidence From BofA—Here's Why Analysts Are Bullish
GitLab Inc. (NASDAQ:) is one of the . On July 10, BofA Securities analyst Koji Ikeda reiterated a 'Buy' rating on the stock with a $72.00 price target. The investment firm came out incrementally positive on GitLab's long-term market potential following a meeting with CEO Bill Staples and CFO Brian Robins. The firm believes that the company's 'Duo strategy' is accurately positioned to gear up increased adoption of premium paid tiers and add-on AI products such as the Duo Pro, Duo Enterprise, and the Agent Platform. Responding to concerns about code generation competitors likely leading to shrinking seats and technological disadvantages for GitLab, the firm noted that they are baseless and that code generation is 'becoming a feature.' Moreover, GitLab's end-to-end developer workflow efficiency remains differentiated. A group of analysts studying data on a large monitor. The firm anticipates GitLab to uphold durable revenue growth exceeding 20% with expanding free cash flow margins over the medium term. It considers them to be 'attractive investment traits.' GitLab Inc. (NASDAQ:GTLB) develops software for the software development lifecycle in the US, Europe, and the Asia Pacific. While we acknowledge the potential of GTLB as an investment, we believe certain AI stocks offer greater upside potential and carry less downside risk. If you're looking for an extremely undervalued AI stock that also stands to benefit significantly from Trump-era tariffs and the onshoring trend, see our free report on the best short-term AI stock. READ NEXT: and . Disclosure: None. Error in retrieving data Sign in to access your portfolio Error in retrieving data Error in retrieving data Error in retrieving data Error in retrieving data
Yahoo
an hour ago
- Yahoo
Tour de France: How many calories will the winner burn?
Imagine you begin pedaling from the start of Stage 12 of 2022's Tour de France. Your very first task would be to bike approximately 20.6 miles (33.2 km) up to the peak of Col du Galibier in the French Alps while gaining around 4,281 feet (1,305 m) of elevation. But this is only the first of three big climbs in your day. Next you face the peak of Col de la Croix de Fer and then end the 102.6-mile (165.1-km) stage by taking on the famous Alpe d'Huez climb with its 21 serpentine turns. On the fittest day of my life, I might not even be able to finish Stage 12 – much less do it in anything remotely close to the five hours or so the winner will take to finish the ride. And Stage 12 is just one of 21 stages that must be completed in the 24 days of the tour. You can listen to more articles from The Conversation, narrated by Noa, here. I am a sports physicist, and I've modeled the Tour de France for nearly two decades using terrain data – like what I described for Stage 12 – and the laws of physics. But I still cannot fathom the physical capabilities needed to complete the world's most famous bike race. Only an elite few humans are capable of completing a Tour de France stage in a time that's measured in hours instead of days. Advertisement The reason they're able to do what the rest of us can only dream of is that these athletes can produce enormous amounts of power. Power is the rate at which cyclists burn energy and the energy they burn comes from the food they eat. And over the course of the Tour de France, the winning cyclist will burn the equivalent of roughly 210 Big Macs. Cycling is a game of watts To make a bicycle move, a Tour de France rider transfers energy from his muscles, through the bicycle and to the wheels that push back on the ground. The faster a rider can put out energy, the greater the power. This rate of energy transfer is often measured in watts. Tour de France cyclists are capable of generating enormous amounts of power for incredibly long periods of time compared to most people. Advertisement For about 20 minutes, a fit recreational cyclist can consistently put out 250 watts to 300 watts. Tour de France cyclists can produce over 400 watts for the same time period. These pros are even capable of hitting 1,000 watts for short bursts of time on a steep uphill – roughly enough power to run a microwave oven. But not all of the energy a Tour de France cyclist puts into his bike gets turned into forward motion. Cyclists battle air resistance and frictional losses between their wheels and the road. They get help from gravity on downhills but they have to fight gravity while climbing. I incorporate all of the physics associated with cyclist power output as well as the effects of gravity, air resistance and friction into my model. Using all that, I estimate that a typical Tour de France winner needs to put out an average of about 325 watts over the roughly 80 hours of the race. Recall that most recreational cyclists would be happy if they could produce 300 watts for just 20 minutes! Racers in the Tour de France need to eat three to four times as many calories as a person does normally. Pietro Agliata/EyeEm via Getty Images Turning food into miles So where do these cyclists get all this energy from? Food, of course! Advertisement But your muscles, like any machine, can't convert 100% of food energy directly into energy output – muscles can be anywhere between 2% efficient when used for activities like swimming and 40% efficient in the heart. In my model, I use an average efficiency of 20%. Knowing this efficiency as well as the energy output needed to win the Tour de France, I can then estimate how much food the winning cyclist needs. Top Tour de France cyclists who complete all 21 stages burn about 120,000 calories during the race – or an average of nearly 6,000 calories per stage. On some of the more difficult mountain stages – like this year's Stage 12 – racers will burn close to 8,000 calories. To make up for these huge energy losses, riders eat delectable treats such as jam rolls, energy bars and mouthwatering 'jels' so they don't waste energy chewing. Tadej Pogačar won both the 2021 and 2020 Tour de France and weighs only 146 pounds (66 kilograms). Tour de France cyclists don't have much fat to burn for energy. They have to keep putting food energy into their bodies so they can put out energy at what seems like a superhuman rate. So this year, while watching a stage of the Tour de France, note how many times the cyclists eat – now you know the reason for all that snacking. This article, published in 2022, is an updated version of a story originally published on June 24, 2021. Advertisement This article is republished from The Conversation, a nonprofit, independent news organization bringing you facts and trustworthy analysis to help you make sense of our complex world. It was written by: John Eric Goff, University of Lynchburg Read more: John Eric Goff does not work for, consult, own shares in or receive funding from any company or organization that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.
