Massive exoplanet discovered using gravitational microlensing method
https://phys.org/news/2017-04-massive-exoplanet-gravitational-microlensing-method.html

Astronomers have found a new massive alien world using the gravitational microlensing technique. The newly detected exoplanet,
designated MOA-2016-BLG-227Lb, is about three times more massive than Jupiter and orbits a distant star approximately 21,000
light years away. The finding was published Apr. 6 in a paper on arXiv.org.

Habitable Planet Reality Check: Kepler 186f Revisited | Drew Ex Machina
http://www.drewexmachina.com/2016/04/17/habitable-planet-reality-check-kepler-186f-revisited/

Landslides on Ceres Reflect Hidden Ice
http://www.news.gatech.edu/2017/04/17/landslides-ceres-reflect-hidden-ice

Massive landslides, similar to those found on Earth, are occurring on the asteroid Ceres. That’s according to a new study led
by the Georgia Institute of Technology, adding to the growing evidence that Ceres retains a significant amount of water ice.

The study is published in the journal Nature Geoscience. It used data from NASA’s Dawn spacecraft to identify three different
types of landslides, or flow features, on the Texas-sized asteroid.

VIRGO: Přenos běží:
NASA TV Public-Education
https://www.youtube.com/watch?v=UdmHHpAsMVw

Za hodinu se otevírá první startokno pro ATK CRS-7! Poprvé ve volitelném pohledu 360 stupňů.
Atlas V Rocket Poised for Space Station Cargo Run Today
http://www.space.com/36493-atlas-v-rocket-cygnus-launching-space-cargo-tuesday.html

Orbital ATK CRS-7 Atlas V Rolls to Launch Pad
https://www.youtube.com/watch?v=4zbQAZpeP58

https://www.nasa.gov/...oddard/2017/nasa-team-explores-using-lisa-pathfinder-as-comet-crumb-detector

LISA Pathfinder, a mission led by ESA (the European Space Agency) with contributions from NASA, has successfully demonstrated
critical technologies needed to build a space-based observatory for detecting ripples in space-time called gravitational waves.
Now a team of NASA scientists hopes to take advantage of the spacecraft's record-breaking sensitivity to map out the distribution
of tiny dust particles shed by asteroids and comets far from Earth.

Most of these particles have masses measured in micrograms, similar to a small grain of sand. But with speeds greater than
22,000 mph (36,000 kph), even micrometeoroids pack a punch. The new measurements could help refine dust models used by researchers
in a variety of studies, from understanding the physics of planet formation to estimating impact risks for current and future spacecraft.

NASA Team Explores Using LISA Pathfinder as a 'Comet Crumb' Detector
https://www.youtube.com/watch?v=c5-mQ62yxt0

OSIRIS-REx is currently 114 million kilometers from Earth. That's roughly 300 times the distance between Earth and the Moon.
Where is the Spacecraft? - OSIRIS-REx Mission
http://www.asteroidmission.org/where-is-the-spacecraft/

Supermassive black holes found in two tiny galaxies | UNews
https://unews.utah.edu/supermassive-black-holes-found-in-two-tiny-galaxies/

Formation of the dwarf galaxy M60-UCD1
https://www.youtube.com/watch?v=KN4AKFF68pE


Three years ago, a University of Utah-led team discovered that an ultra-compact dwarf galaxy contained a supermassive black hole, then the smallest known galaxy to harbor such a giant
black hole. The findings suggested that the dwarfs were likely tiny leftovers of larger galaxies that were stripped of their outer layers after colliding into other, larger galaxies.

Now, the same group of U astronomers and colleagues have found two more ultra-compact dwarf galaxies with supermassive black holes. Together, the three examples suggest that black holes
lurk at the center of most of these objects, potentially doubling the number of supermassive black holes known in the universe. The black holes make up a high percentage of the compact
galaxies’ total mass, supporting the theory that the dwarfs are remnants of massive galaxies that were ripped apart by larger galaxies.

Penn Researchers Provide New Insight Into Dark Matter Halos | Penn News
https://news.upenn.edu/news/penn-researchers-provide-new-insight-dark-matter-halos

Research from the University of Pennsylvania could shed light on the distribution of one of the most mysterious substances in the universe.

In the 1970s, scientists noticed something strange about the motion of galaxies. All the matter at the edge of spiral galaxies was rotating just
as fast as material in the inner part of the galaxy. But according to the laws of gravity, objects on the outskirts should be moving slower.

Many scientists now believe that more than 80 percent of the matter of the universe is locked away in mysterious, as yet undetected, particles of
dark matter, which affect everything from how objects move within a galaxy to how galaxies and galaxy clusters clump together in the first place.

This dark matter extends far beyond the reach of the furthest stars in the galaxy, forming what scientists call a dark matter halo. While stars
within the galaxy all rotate in a neat, organized disk, these dark matter particles are like a swarm of bees, moving chaotically in random
directions, which keeps them puffed up to balance the inward pull of gravity.

A Search For the Theory of Everything - The Great Courses Daily
http://www.thegreatcoursesdaily.com/the-theory-of-everything/

The unifying theories of physics are among the greatest and most complex in all of science; their progression toward ever-grander
insights will transform our understanding of the universe, and is nothing less than a search for the theory of everything.

The Lifetimes of Massive Star-Forming Regionssu201714 | www.cfa.harvard.edu/
https://www.cfa.harvard.edu/news/su201714

Astronomers can roughly estimate how long it takes for a new star to form: it is the time it takes for material in a gas cloud to collapse in free-fall,
and is set by the mass, the size of the cloud, and gravity. Although an approximation, this scenario of quick, dynamic star formation is consistent with
many observations, especially of sources where new material can flow into the cloud, perhaps along filaments, to sustain steady activity. But this simple
picture might not apply in the largest systems with star clusters and high-mass stars. Rather than a quick collapse, the process there might be inhibited
by pressure, turbulence, or other activities that slow it down.

CfA astronomer Cara Battersby and two colleagues studied the formation, early evolution, and lifetimes of high-mass star-forming regions and their earliest
evolutionary phases in dense, molecular regions. These clumps have densities of gas as high as ten million molecules per cubic centimeter (tens of thousands
of times higher than typical in gas clouds); the dust associated with this gas blocks the external starlight, leaving the material very cold, only a few tens
of degrees above absolute zero. The usual method for identifying these clumps is with submillimeter telescopes, which take images of the sky; automated
algorithms can then process the images to identify and characterize cold clumps. The problem is that even a quiescent clump can contain subregions of activity
that are not spotted with the relatively poor spatial resolutions of the submillimeter telescopes used to assemble catalogs of these regions.