Earth-Size, Habitable-Zone Planet Found Hidden In Early NASA Kepler Data (phys.org) 71
A team of transatlantic scientists, using reanalyzed data from NASA's Kepler space telescope, has discovered an Earth-size exoplanet orbiting in its star's habitable zone, the area around a star where a rocky planet could support liquid water. Phys.Org reports: Scientists discovered this planet, called Kepler-1649c, when looking through old observations from Kepler, which the agency retired in 2018. While previous searches with a computer algorithm misidentified it, researchers reviewing Kepler data took a second look at the signature and recognized it as a planet. Out of all the exoplanets found by Kepler, this distant world -- located 300 light-years from Earth -- is most similar to Earth in size and estimated temperature.
This newly revealed world is only 1.06 times larger than our own planet. Also, the amount of starlight it receives from its host star is 75% of the amount of light Earth receives from our Sun -- meaning the exoplanet's temperature may be similar to our planet's as well. But unlike Earth, it orbits a red dwarf. Though none have been observed in this system, this type of star is known for stellar flare-ups that may make a planet's environment challenging for any potential life. There is still much that is unknown about Kepler-1649c, including its atmosphere, which could affect the planet's temperature. Current calculations of the planet's size have significant margins of error, as do all values in astronomy when studying objects so far away. But based on what is known, Kepler-1649c is especially intriguing for scientists looking for worlds with potentially habitable conditions.
This newly revealed world is only 1.06 times larger than our own planet. Also, the amount of starlight it receives from its host star is 75% of the amount of light Earth receives from our Sun -- meaning the exoplanet's temperature may be similar to our planet's as well. But unlike Earth, it orbits a red dwarf. Though none have been observed in this system, this type of star is known for stellar flare-ups that may make a planet's environment challenging for any potential life. There is still much that is unknown about Kepler-1649c, including its atmosphere, which could affect the planet's temperature. Current calculations of the planet's size have significant margins of error, as do all values in astronomy when studying objects so far away. But based on what is known, Kepler-1649c is especially intriguing for scientists looking for worlds with potentially habitable conditions.
The star is class M (Score:4, Interesting)
Re:The star is class M (Score:5, Funny)
Or we could send the Space Force. One has the mental picture of fit storm trooper types dressed in Girl Scout uniforms in Fake Orange Wigs with a "Force by Trump" insignia on the the uniform to assure the alien natives they mean harm.
Re: The star is class M (Score:1)
You have that mental picture, anyway. Perhaps get out more and work on lessening your TDS. You're just the flipside of the Obama haters. So predictable and boring.
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Or we could send the Space Force. One has the mental picture of fit storm trooper types dressed in Girl Scout uniforms in Fake Orange Wigs with a "Force by Trump" insignia on the the uniform to assure the alien natives they mean harm.
I hear the women's patches read "Forced by Trump", but I digress.
Re:The star is class M (Score:5, Informative)
M class stars are highly energetic in the UV and X-Ray spectra and with large solar flares. This will strip any atmosphere and surface water quickly from the planet and as the planet is close to the star this will tidally lock the planet so one side faces the star at all times. This is a scenario for a non habitable planet.
https://en.wikipedia.org/wiki/... [wikipedia.org] for the details on why these stars will not have habitable planets, but as they comprise 80+% of the stars out there these systems will be found regularly and always disappoint.
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they comprise 80+% of the stars out there these systems will be found regularly and always disappoint.
Like the Kardashians
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On the other hand, nothing stops the first several kilometers of the subsurface from being a cradle for life, in fact that is one of the scenarios for the origin of Earth life.
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This is not Star Trek but real science, I feel sorry for all the people answering ... o ... oh ... wait ...
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Too many people (footnote) can't tell the difference.
footnote "Too many" defined as more than two.
watch all the nearby stars (Score:2)
Why can't we watch all the nearby stars for long periods of time? Periods meaning earth-like transits.
Instead of a constellation of internet satellites, can we have one of space telescopes that are watching specific stars for transits? When one passes out of view, the next satellite takes over?
Of course this may be expensive, but is it possible for a constellation of small, far out satellites, instead of giant ones like Kepler, J Webb, etc?
Re:watch all the nearby stars (Score:5, Insightful)
You're looking for ridiculously small variations in output. Like the sun is 100 times the radius of the Earth meaning 10000 the area. So you're looking at a drop of 0.01% for the very brief period Earth is directly in the path of the sun. If your satellite isn't sensitive enough to register that reliability, it doesn't matter how many observations you have. So here bigger is better.
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You're looking for ridiculously small variations in output.
Right. In more detail:
Why can't we watch all the nearby stars for long periods of time? Periods meaning earth-like transits.
Well, of course, we'd like to. That's a lot of telescope time, though.
Instead of a constellation of internet satellites, can we have one of space telescopes that are watching specific stars for transits?
To find a planet requires high accuracy for a period of multiple years (for a planet at Earth's distance), and you have a 1% shot of an Earthlike planet being at the right angle to detect. So, you're talking a hundred space telescopes to detect one planet.
When one passes out of view, the next satellite takes over?
No. The accuracy required is too high; you can't match the detectors. The transit dimming is only 100 micromagnitudes deep. It has to be the same detector and
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To find a planet requires high accuracy for a period of multiple years (for a planet at Earth's distance), and you have a 1% shot of an Earthlike planet being at the right angle to detect. So, you're talking a hundred space telescopes to detect one planet.
..and, to clarify, the way we currently deal with this (on Kepler or TESS) is to have one telescope looking at a lot of stars, not one telescope dedicated to staring at at just one star.
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Your point is pretty mood, as that is exactly how 1/3rd of all planets are detected.
It is called "the transit method"
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The gigantic international war machine is why. NASA for instance gets 0.45% of the US budget and has stayed near that level since the 1980s. The Pentagram (not counting the Black Budget or the alphabet soup of intel agencies) on the other hand has reliably been sucking down 40-55% of the budget every year since the 1950s.
All NASA budgets since its founding combined: $650 billion
US military budget just last year: $750 billion
Re: watch all the nearby stars (Score:1)
The massive Pentagon budget includes huge health care and pension funding for veterans. But keep nursing those daddy warbucks delusions if it justifies your beliefs
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Less than a quarter of its budget, so even after subtracting that we still spend more on the Pentagram than twice the next largest military budget in the world (and that's only if you pretend that China spends $0 for pensions and benefits). Are you really all such cowards that you need to impoverish the entire fucking planet buying war toys?
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Social Security, Medicare and Medicaid are self-funded programs and not budget items. You can argue about the mechanisms of them, but they're not discretionary items like the military or space program. All other "social programs" combined don't approach the budget of the Pentagram.
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To get part-per million stability you need for transit measurements you need thermal stability, electrical stability, optical stability, pointing stability. All of those are incompatible with a very small satellite. If you know better, feel free to apply to NASA (or ESO, or J
Re: watch all the nearby stars (Score:1)
I'm skilled and looking for a career change, so why not?
None of the other posters in this thread said it wasn't possible. (Just that they couldn't do it.)
Thanks for your comment!
Good (Score:1)
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Re: Good (Score:1)
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Just have to maintain a constant acceleration of 1g
That's the hard part. The easy part of course is inventing the magical unicorn, rainbow and fairy dust engine that can both do this as well as have fuel left over to also do it on the other end to slow down... Should only take you a couple weeks to design it. Let us know when you have the prototype ready.
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Just have to maintain a constant acceleration of 1g. Then it will only take 11.1 years to travel 300 light years. Of course 302 years will have elapsed on Earth.
Besides the (wrong) calculation, I doubt our friend to be mass-less :-)
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There is nothing wrong with the calculation.
Hint: constant acceleration.
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Good luck traveling 300 light-years before the heat death of the universe.
Fixed that for you... Funny how people's minds just shut down around big numbers.
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Fixed that for you... Funny how people's minds just shut down around big numbers.
So did yours... Voyager I will take about 5 million years to travel 300 light years. That's not even a tenth of the time since the dinosaurs. And Voyager is not the best we can do, even without getting into fission/fusion/antimatter concepts.
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Yeah, like that useless quantum mechanics physicists were so hot about in the early 20th century. What a useless boondoggle that was.
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So, your great-great(repeated 15 or so times)-grandfather would get to see this? Interesting.
Do note that there is a fundamental difference between "ancestor" and "descendant". Because it makes you look like an idiot when you use the wrong one....
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Yeah, got me there! I apologize for using the wrong word. No excuses... English is not my first language, but I know the difference.
Have a great day!
E
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Back in 1996... (Score:2)
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We are not looking for 6Mm radius planets 1AU from yellow dwarves. We do not have the technology to spot them. Both the dip in the light and the gravity wobble are too small to measure with current instruments. Even for Alpha Centauri, it seems.
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Did you have a rational basis for this hope?
If so, what was it?
"A team of transatlantic scientists"? (Score:4, Informative)
Do they only work on board ship or something? Perhaps it was a transatlantic team of scientists?
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They eat a lot of twinkies.
Hop Skip and a Jump (Score:2)
if we hopped aboard the space shuttle discovery, which can travel 5 miles a second, it would take us about 37,200 years to go one light-year. So, 37,200 x 300 = oh shit.
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You could always travel as a meat Popsicle. Hopefully there's intelligent life at the other end to thaw you out.
You mean, while your ship and cooling system remained functioning for 11,160,000 years?
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Twice the size of Earth? (Score:3)
"This newly revealed world is only 1.06 times larger than our own planet."
If it is 1 times larger than the Earth, it would be twice as large, and this one is 1.06 times larger. Or did the author mean to say it was 1.06 times as large as our own planet. The graphic in the article seems to show that it is 1.06 times the size of the Earth, not 2.06 times like the author, Felicia Chou of the Jet Propulsion Laboratory, states. The author is probably more focused on science, than writing.
And yes, size matters. (:
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It's one times larger not one times the size. You are calculating one times the size, one times larger means you add one more to get the size.
Re: Twice the size of Earth? (Score:2)
1+1.06=2.06.
Larger means you add to what is there.
If the a liter bottle is replaced with one that is 20% larger does that mean it is 0.20 liter size?
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It would help if they gave the volume in olympic swimming pools, or the diameter in Smoots.
Communicating with ET Will Take A While (Score:2)
If we send a message, will future generations even remember we sent it before the reply comes?
But is it tidally locked? (Score:2)
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The more exoplanets we discover, the more that the "rare earth" hypothesis as a solution to Fermi's paradox looks to be the correct explanation. We are approaching 5,000 known exoplanets, and none really look like fantastic candidates for life. The few rocky planets in the habitable zones we've found seem to be tidally locked, or orbiting a start that appears to have characteristics hostile to life.
There's almost certainly habitable planets in the universe, but if they are all 10,000+ light years away, they
Earth is special for life (Score:2)
The Fermi paradox is all you need to know that we were put here special.
its nothing (Score:1)
Proxima (Score:1)