Kepler-186f is the first Earth-sized planet ever found that also orbits in its star’s habitable zone. Although its size and orbit are known, its mass and composition are not - however, existing models suggest that it could have a rocky terrain and an atmosphere, making it potentially the most Earth-like planet discovered so far.
Seven explorers are about to embark upon an 80-day simulated mission to Mars.
On Saturday (Sept. 24), the crewmembers of the Mars 80 mission — who hail from France, Japan, Russia, Australia, India and Canada — will begin work at the Mars Desert Research Station (MDRS), a facility in the Utah desert run by the nonprofit Mars Society.
The team will conduct a campaign of geology, microbiology and paleontology research in the area, operating under many of the same pressures and constraints that real-life Mars pioneers would face. Crewmembers will also test out spacesuit technologies and other gear that could help humanity get a foothold on the Red Planet, Mars Society representatives said.
This rich starfield spans almost 10 degrees across the sky toward the northern constellations Cassiopeia and Perseus. On the left, heart-shaped cosmic cloud IC 1805 and IC 1848 are popularly known as the Heart and Soul nebulae. Easy to spot on the right are star clusters NGC 869 and
NGC 884 also known as h and Chi Perseii, or just the Double Cluster.
Heart and Soul, with their own embedded clusters of young stars a million or so years old, are each over 200 light-years across and 6 to 7 thousand light-years away. In fact, they are part of a large, active star forming complex sprawling along the Perseus spiral arm of our Milky Way Galaxy. The Double Cluster is located at about the same distance as the Heart and Soul nebulae. Separated by only a few hundred light-years, h and Chi Perseii are physically close together, and both clusters are estimated to be about 13 million years old. Their proximity and similar stellar ages suggest both clusters are likely a product of the same star-forming region.
Two of our nearest galactic neighbours, the Large and Small Magellanic Clouds, hang in the night-time sky above an ALMA antenna in this captivating image.
ALMA, the largest ground-based astronomical project in existence, comprises 66 such high-precision antennas set high in the Chilean Andes on the Chajnantor plateau. By observing millimetre and submillimetre radiation, ALMA opens a window into the enigmatic cold Universe.
Ask Ethan: What ‘Impossible Physics’ Would Be Possible With Warp Drive?
“See ourselves as we were in the past. You can’t use warp drive to travel back in time, but if you can outrace the light that the Earth, Sun or Milky Way emitted so long ago, you can then “catch” it with the proper tools. Warp yourself to 65 million light years away, and with a good enough telescope, you can see the asteroid that wiped out the dinosaurs. Warp to 12,000 light years away, and you can see the end of the last ice age. Warp to 53 light years away and watch, for yourself, who really shot JFK. Or go back to 4.5 billion light years away, and watch our Solar System as it’s first being born. Warp drive, coupled with a powerful enough telescope, would suddenly become the ultimate forensic tool.”
When Star Trek debuted 50 years ago, we didn’t know that there would be regions of the Universe that were forever inaccessible to humanity, nor that there would be galaxies permanently unreachable to us, even if we managed to develop near-light-speed travel technology. Yet thanks to the existence and dominance of dark energy today, that’s exactly the case. The only workaround, it appears, would be to develop faster-than-light travel. But with the physical possibility of the Alcubierre solution to General Relativity, which would enable warp drive, this might actually render these distant, unreachable regions someday traversable. Not only that, but a whole slew of other “physical impossibilities” would suddenly become possible, enabling us to perform acts that physics without warp travel would simply never allow.