The second-closest exoplanet beyond our solar system may sound like a cold, alien and inhospitable place, but what if it's not? What if, as new research suggests, there are pockets of habitable environments deep below its icy surface, assuming it can produce heat from its core? Discovered late in 2018, Barnard's Star b is like none of the planets in the solar system . With a mass of three times that of Earth, this enigmatic planet is known as a "super-Earth," probably a rocky planet that occupies a mass range between Earth and the smaller gas giants, like Neptune. Exoplanet-hunting missions like Kepler have found that super-Earths are common throughout the galaxy, so Barnard's Star is more than just a curiosity, it could become the key for us to understand how they formed, what they're made of and,
After a painstaking search through two decades of spectroscopic data of Barnard's Star, astronomers announced the new world's discovery in November. They found a 233 day "wobble" that was mentioned in the exoplanet at approximately the same distance at which Mercury orbits our sun, very slightly tugging at its star as it orbited. But, the star is a low-mass and dim red dwarf, the planet's orbit puts it beyond the star's "habitable zone" and into its "snow line." If Barnard's Star b has any water on its surface, it will be frozen, and not conducive to supporting life (as we know it).
However, according to new research presented at the 23rd meeting of the American Astronomy Society (AAS ) in Seattle, Washington, Jan. 1
"Geothermal heating could support" life zones "under its surface, akin to subsurface lakes found in Antarctica, "said astrophysicist Edward Guinan, or Villanova University, in a statement. "The surface temperature on Jupiter's icy moon is similar to Barnard's but because of tidal heating, Europe probably has liquid oceans under its icy surface." Astrobiologists have long been fascinated with Europe. Even though it is orbits Jupiter well outside our sun's habitable zone and has very obvious thick-ice crust, through tidal interactions with the gas giant, its core produces heat that maintains a subsurface ocean in a liquid water state. Decades of observations of the moon have revealed that the ocean may have sufficient quantities of oxygen and nutrients to support a hypothetical marine ecosystem.
Barnard's Star is much larger than Europe and cannot have the same degree of tidal heating experienced by the Jovian moon, but it should have a large and hot iron / nickel core, Guinan and his co-investigators suspect that its geothermal activity could be primitive life-forms. Alas, we are getting ahead of ourselves. Barnard's Star may well be habitable, but currently we only know its mass and orbital period around the star. We know nothing about its composition, atmosphere (if it even has one) or physical size. It will undoubtedly be cold, as the star only generates 0.4 percent of the radiant power of our sun, but does it have water ice? Does it have geothermal activity?
Barnard's Star is only six light-years from Earth, so it's conceivable that the future generation of powerful telescopes will have the observation power to study the world of alien. According to the researchers, such observations will shed light on the nature of the planet's atmosphere, surface and potential habitability.
"The most significant aspect of the discovery of Barnard's star b is that the two nearest star systems to the sun are now known to host planets, "said Engle in the same statement. "This supports previous studies based on Kepler mission data, which can be very common throughout the galaxy, even numbering in the tens of billions."
The closest exoplanet to Earth is Proxima Centauri b, and Earth-sized world that orbits its red dwarf is located inside the habitable zone, the distance around a star that could allow a planet to have liquid water on its surface. On paper, this sounds like a fantastic location to seek out alien life, but Proxima Centauri is an angry little star, known for its violent flares that would irradiate any planet orbits too close. Barnard's Star orbits its red dwarf farther away and, if life can find its way under its surface, could be shielded from any ionizing radiation.