Planetary Discovery around Ultracool Star (Earth-sized planet found 13,000 ly away!)

Centauri Dreams ^ | 4/28/17 | Paul Gilster

[LibWhacker]

Planetary Discovery around Ultracool Star

by Paul Gilster on April 28, 2017

I have a special enthusiasm for microlensing as a means of exoplanet discovery. With microlensing, you never know what you’re going to come up with. Transits are easier to detect when the planet is close to its star, and hence transits more frequently. Radial velocity likewise sends its loudest signal when a planet is large and close. Microlensing, detecting the ‘bending’ of light from a background object as it is affected by a nearer star’s gravitational field, can turn up a planet whether near to its star or far, and in a wide range of masses. It can also be used to study planetary populations as distant as the galactic bulge and beyond.

Now we have news of a cold planet about the size of the Earth orbiting what may turn out to be a brown dwarf, and is in any case no more than 7.8 percent the mass of our Sun. Is this an object like TRAPPIST-1, the ultra-cool dwarf star we’ve had so much to say about in recent days as investigations of its 7 planets continue? If so, the planet OGLE-2016-BLG-1195Lb is in no way as interesting from an astrobiological point of view. It’s probably colder than Pluto. It is also the lowest-mass planet ever found using the microlensing technique.

Image: This artist’s concept shows OGLE-2016-BLG-1195Lb, reported in a 2017 study in the Astrophysical Journal Letters. Study authors used the Korea Microlensing Telescope Network (KMTNet), operated by the Korea Astronomy and Space Science Institute, and NASA’s Spitzer Space Telescope, to track the microlensing event and find the planet. Credit: NASA/JPL-Caltech.

But don’t think this frigid world, about 13000 light years away, doesn’t have its uses. It is part of an ongoing investigation into the distribution of planets in the galaxy. The OGLE designation signifies the ground-based Optical Gravitational Lensing Experiment survey, run by the University of Warsaw, which alerted astronomers to the initial microlensing event. The authors of the study on OGLE-2016-BLG-1195Lb then used the Korea Microlensing Telescope Network (KMTNet) as well as the Spitzer space telescope to study the outcome.

With this planet, we are at the lowest end of what microlensing can detect with current methods. We’ll need to get to NASA’s upcoming Wide Field Infrared Survey Telescope (WFIRST) to begin finding smaller bodies than this. Tuning up the method will be useful as we work on understanding how planets are distributed in the Milky Way, since microlensing can find planets at distances far beyond the capabilities of other detection methods. Specifically, will we find a difference in the planet populations of the Milky Way’s central bulge as compared to its disk? OGLE-2016-BLG-1195Lb is a member of the disk population.

“Although we only have a handful of planetary systems with well-determined distances that are this far outside our solar system, the lack of Spitzer detections in the bulge suggests that planets may be less common toward the center of our galaxy than in the disk,” says Geoff Bryden, astronomer at JPL and co-author of the study.

Let’s dig a little deeper, though, into planet formation around ultracool stars. A 2007 paper by Matthew Payne and Giuseppe Lodato looked at the core accretion method of planet formation in the context of very low mass stars and brown dwarfs, arguing that if such objects have protoplanetary disks in the range of several Jupiter masses, then Earth-mass planets should be frequent around them, typically at about 1 AU from the star. But if brown dwarf disks contain less than a Jupiter mass of material, then they probably cannot form a planet.

The OGLE-2016-BLG-1195Lb paper runs through the scholarship, including a 2013 study from Daniel Apai showing that disks occur as frequently around ultracool dwarfs as around Sun-like stars. And a 2016 paper from Leonardo Testi and colleagues found evidence for dusty disks around 11 of 17 young brown dwarfs studied. A Herschel study from Sebastian Daemgen and team, likewise in 2016, found that half of the ultracool dwarf disks it examined were of at least one Jupiter mass.

So we’re making progress at learning about planet formation in ultracool environments, and here again microlensing comes to the fore. Stars this faint, and their even fainter planets, are a tough challenge for most planetary detection methods, though four have been found with direct imaging. Microlensing does not rely on light from the system being studied, but it can give us information about the planetary and stellar masses involved. And indeed, we have four previous microlensing events that have found planets around ultracool dwarfs.

Two of these previous microlensing detections show planets as small as a few Earth masses, and OGLE-2016-BLG-1195Lb lowers the detected mass still further. From the paper:

These [previous discoveries] suggest that the protoplanetary disks of ultracool dwarfs have sufficient mass to form terrestrial planets, as also hinted at by direct imaging of such disks. The location of these planets, at about 1 AU, support planet formation predictions. However, since the sensitivity of current microlensing surveys for systems with such small mass ratios is very narrow, around projected separations of ∼1AU, they cannot set strong constraints on the presence of planets elsewhere around ultracool dwarfs, such as the much closer separations seen in the TRAPPIST-1 system.

Small planets may be common around ultracool dwarfs, an idea that previous microlensing discoveries reinforce, along with the work on protoplanetary disks and the seven planets orbiting TRAPPIST-1. As to our expectations regarding planets in the galactic bulge as opposed to the disk, the jury is still out. The planets Spitzer has thus far found in its microlensing campaign for the galactic distribution of planets are all located in the disk. We have two upcoming Spitzer microlensing campaigns, one this year and one next, which should offer additional insights. The key question: Is the galactic bulge deficient in planets?

The paper is Shvartzvald et al., “An Earth-mass Planet in a 1-AU Orbit around an Ultracool Dwarf,” accepted at Astrophysical Journal Letters (preprint).

[LibWhacker]

Wow, I've heard of gravitational lensing, but never microlensing. This is only the third planet they've ever discovered with the technique (in 10 years or so of trying!). So it's not too embarrassing that I've never heard of it. If you're similarly in the dark, here's a cool little layman's intro. I particularly liked their discussion of the advantages and disadvantages of microlensing. Enjoy!

Illustrates how the introduction of a planet can complicate ordinary gravitational lensing.

[BenLurkin]

Voyager is traveling at eleven miles per second. How long would t take to get there.

[GraceG]

13,000LY may as well be 13 billion Ly away given our current technology

[Beowulf9]

So far away has to be cold as, well cold.

[Telepathic Intruder]

Voyager was of course not designed to travel to other stars. But, given time, it could. In this case a mere 220 million years. It’s battery is already dying, however.

[LibWhacker]

(13000 x 6000000000000) / (11 x 3600 x 24 x 365) = 225 million years. But no one is talking about going there yet, thank goodness!

[jonrick46]

It is strange that with all the possible planets that could support intelligent life, that not one has been found that has generated that type of electromagnetic transmission we call radio.

[LibWhacker]

Life-bearing planets may be exceedingly rare and we just haven’t seen one yet. Thus, no radio signals. Also, radio signals used for terrestrial communication aren’t powerful enough to be easily detected that far out in interstellar space.

[MNDude]

And another 250 million years for a to get back here.

[Samurai_Jack]

We keep looking in the radiation bands for communication methods. Because the speed of light is finite these don’t seem to be the most efficient for light year distance communications. A extra terrestrial species with the ability to communicate outside of their own space could be communicating in an entirely different manner. Maybe they’ve untangled the nature of ‘dark matter’ or have mastered interdimensional access.

My point is that the galaxy could be densely populated and we wouldn’t know it because we’re only considering that life will communicate on the EM radiation band. But the universe is not only stranger than we imagine, it’s much more strange than we have the capacity to imagine.

[Flick Lives]

Mamma always said, with microlensing, you never know what you’re going to come up with.

[Flick Lives]

It is strange that with all the possible planets that could support intelligent life, that not one has been found that has generated that type of electromagnetic transmission we call radio.

Several factors work against detecting extraterrestrial radio transmissions.

One is it requires a tool-building species. There may be many alien species with high intelligence on other planets, but if they're not tool-builders, we'll never detect them. Think of a species like whales. Apparently quite intelligent. They even have music. But with those little flippers they have it makes it difficult to build anything.

Another factor is radio transmissions simply are not powerful enough and they get scattered and absorbed over interstellar distances.

The third factor is the narrow time-band where a civilization may actually use radio transmission. On Earth, we've been using radio transmission for about a century, a tiny fraction of time on a cosmic scale. Other alien races may have ascended, declined, and extinguished themselves millions of years before.

It is rather cool to speculate on however small the chance, of picking up the alien equivalent of "I Love Lucy" from some alien world.

[LibWhacker]

Yep, it’s like looking for smoke signals... Ain’t gonna find any.

[LibWhacker]

I love this graphic:

[Flick Lives]

Cool graphic. And this is just our own galaxy. One among 100 billion!

[Deplorable American1776]

I wish there was a planet that would accept liberals, like Soros, Al Gore, Michael Moore and Leonardo DiCaprio. But then, if they do have INTELLIGENT LIFE, they would be CONSERVATIVE!!!

[lurk]

Only 13000 light years away. They write like it’s doable.

[Moltke]

You forgot to factor in leap years. Shaves a whole lot of time off that trip!

[Moltke]

If that little spot is us, who took that photo????

[Larry Lucido]

How "ultracool" is it?