Join Dr. Svetlana Berdyugina and Dr. Jeff Kuhn from the PLANETS Foundation as they discuss a new technique they've
developed that allows astronomers to directly image the surfaces of Earth-sized exoplanets like Proxima Centauri b.

Imaging the Surface of Proxima Centauri b
https://www.youtube.com/watch?v=LYMHuOXmFrc

In experiments on Earth, testing possible building blocks of alien life: Subjecting artificial amino acids to extreme conditions, researchers hunt for clues on what it takes to survive on other planets -- ScienceDaily
https://www.sciencedaily.com/releases/2017/04/170424084021.htm

Scientists are attempting to identify the amino acids - building blocks that make proteins and support all life on Earth -
that might feasibly form the basis of extraterrestrial life. The researchers have analyzed how an assortment of 15 amino acids,
some found here on Earth in living organisms and some not found in living organisms on Earth, hold up in the face of extreme
conditions found on other planets and moons.

Tension in the Hubble constant – Triton Station
https://tritonstation.wordpress.com/2017/02/27/tension-in-the-hubble-constant/

There has been some hand-wringing of late about the tension between the value of the expansion rate of the universe – the famous Hubble constant,
H0, measured directly from observed redshifts and distances, and that obtained by multi-parameter fits to the cosmic microwave background. Direct
determinations consistently give values in the low to mid-70s, like Riess et al. (2016): H0 = 73.24 ± 1.74 km/s/Mpc while the latest CMB fit from
Planck gives H0 = 67.8 ± 0.9 km/s/Mpc. These are formally discrepant at a modest level: enough to be annoying, but not enough to be conclusive.

The widespread presumption is that there is a subtle systematic error somewhere. Who is to blame depends on what you work on. People who work on
the CMB and appreciate its phenomenal sensitivity to cosmic geometry generally presume the problem is with galaxy measurements. To people who work
on local galaxies, the CMB value is a non-starter.

This subject has a long and sordid history which entire books have been written about. Many systematic errors have plagued the cosmic distance
ladder. Hubble’s earliest (c. 1930) estimate of H0 = 500 km/s/Mpc was an order of magnitude off, and made the universe impossibly young by what
was known to geologists at the time. Recalibration of the distance scale brought the number steadily down. There followed a long (1960s – 1990s)
stand-off between H0 = 50 as advocated by Sandage and 100 as advocated by de Vaucouleurs. Obviously, there were some pernicious systematic errors
lurking about. Given this history, it is easy to imagine that even today there persists some subtle systematic error in local galaxy distance
measurements.

The Late Heavy Bombardment: A Violent Assault on Young Earth
http://www.space.com/36661-late-heavy-bombardment.html

Early Earth suffered constant threat of attack from leftover planet-building material. From about 4.5 to 3.8 billion years ago,
failed planets and smaller asteroids slammed into larger worlds, scarring their surface. Near the end of the violence, during
a period known as the Late Heavy Bombardment, impacts in the solar system may have increased. The increased activity
most likely came from the movement of the giant planets, which sent debris raining down on the smaller rocky worlds.

Techniques and Methods for Astrophysical Data Visualization - Publications of the Astronomical Society of the Pacific - IOPscience
http://iopscience.iop.org/...8-3873/page/Techniques-and-Methods-for-Astrophysical-Data-Visualization

Astrophysics continues to be a leader in the data sciences, with innovative methods being developed to handle new analysis challenges.
The higher rates of data acquisition in both observational and theoretical astrophysics demand innovative solutions in scientific visualization.
The Publications of the Astronomical Society of the Pacific (PASP) has published a special focus issue titled Techniques and Methods for
Astrophysical Data Visualization.

Techniques and Methods for Astrophysical Data Visualization
https://www.youtube.com/watch?v=AACsyyr_NZs

WATCH LIVE @ 7 pm ET: Webcast about Epic Gravitational Wave Discovery
http://www.space.com/17933-nasa-television-webcasts-live-space-tv.html

Black Hole Blues and Other Songs from Outer Space
https://www.youtube.com/watch?v=2QitI_tvOR0

'Hot Jupiter' transiting a rapidly-rotating star discovered
https://phys.org/news/2017-05-hot-jupiter-transiting-rapidly-rotating-star.html

A "hot Jupiter" exoplanet transiting a rapidly rotating star has been discovered jointly by WASP and KELT survey, a new study reveals. The newly found alien world,
designated WASP-167b/KELT-13b, is several times more massive than Jupiter and orbits its parent star every two days. The finding was presented Apr. 25 in a paper
published on the arXiv pre-print repository.

The new giant planet was detected by a team of astronomers led by Lorna Temple of Keele University in Newcastle, U.K. The discovery is the result of two exoplanet
surveys, namely the Wide Angle Search for Planets (WASP) and the Kilodegree Extremely Little Telescope (KELT). WASP observations, using the WASP-South telescope of
the South African Astronomical Observatory (SAAO) in South Africa were carried out between May 2006 and June 2012. The KELT observing campaign, utilizing SAAO's
KELT-South telescope, started in March 2010 and lasted till August 2013.

WASP-167/KELT-13 is a 1.3 billion-year-old F1V star with a rotation period estimated to be shorter than 1.8 days. With a radius of about 1.79 solar radii, this star
is approximately 60 percent more massive than our sun. WASP-167/KELT-13 was observed by WASP and KELT teams independently from each other, and resulted in
the detection of a planet-like transit signal.

Comparison of the Small Magellanic Cloud in infrared and visible light | ESO Australia
http://www.eso.org/public/australia/videos/eso1714c/

Comparison of the Small Magellanic Cloud in infrared and visible light
https://www.youtube.com/watch?v=0HakriviJJU

VISTA odhaluje prachový závoj Malého Magellanova oblaku | ESO Česko
https://www.eso.org/public/czechrepublic/news/eso1714/?lang

ESOcast 105 Light: Starstruck by the Small Magellanic Cloud (4K UHD)
https://www.youtube.com/watch?v=bVgEhvhNfPM


Blízká trpasličí galaxie známá jako Malý Magellanův oblak je nápadným objektem jižní oblohy i při pozorování pouhým okem. Běžné dalekohledy pracující
s viditelným světlem ale neumožňují nahlédnout do nitra této galaxie, které je zastíněno značným množstvím mezihvězdného prachu. Dalekohled VISTA byl však
navržen pro pozorování v infračerveném pásmu elektromagnetického záření a dovoluje astronomům spatřit myriády hvězd této sousední galaxie v dosud nevídaných
detailech. Výsledkem provedených pozorování je tento unikátní záběr – největší infračervený snímek Malého Magellanova oblaku zaplněný miliony hvězd.

Researchers present first results of solar observations with the Siberian Radioheliograph
https://phys.org/news/2017-05-results-solar-siberian-radioheliograph.html

Russian scientists have presented the first results of solar observations made with the new radioheliograph of the Siberian Solar Radio Telescope
(SSRT). The Siberian Radioheliograph (SRH), has recently commenced regular observations of active processes in the sun's atmosphere, which will
allow better monitoring of solar activity. Results of the initial SRH observations were described in a paper published Apr. 25 on arXiv.org.

SRH is a 48‑antenna array with a 4–8 GHz operating frequency range and a 10 MHz instantaneous receiving band. The instrument is installed on
the SSRT telescope of the Radioastrophysical Observatory (RAO), located in the Eastern Sayan Mountains, about 220 kilometers away from Irkutsk.

Astronomer ponders the idea of looking for long extinct intelligent alien life
https://phys.org/news/2017-05-astronomer-ponders-idea-extinct-intelligent.html

Jason Wright, an astronomy professor at Penn State, has uploaded a paper to the arXiv preprint sever that addresses the issue of whether we have looked hard
enough for extinct alien life—particularly intelligent forms of extraterrestrial life. In his paper, he questions whether enough effort is being put into looking for
evidence of space-faring alien life forms (technosignatures) that are now extinct but who might have left behind evidence of their existence here in our own solar
system—everything here is much closer, he notes, than the next-nearest star system.

To be clear, Wright is not suggesting that he believes such forms of life once existed or that there is any evidence of them, as some in the media have suggested.
Instead, he is merely suggesting that as part of a thorough search for alien life forms, we ought to include those that might once have been nearby, but who, for
whatever reason, either left or went extinct. He notes that most current research involved in looking for life beyond Earth is focused on finding biosignatures—
evidence of extraterrestrial life that is still alive today, including simple microbes.

Evidence of extinct aliens would likely be difficult if not impossible to find on Earth, he notes, due to plate tectonics, weather etc., if timelines of millions
of years are considered. But other bodies in the solar system are capable of holding onto material for very long time periods due to subsurface features that offer
protection from meteor strikes and solar radiation—examples might include asteroids or moons, which, if aliens did ever visit our solar system, would have provided
both shelter and privacy. He notes that technosignatures could come in a variety of forms—from evidence of mining to materials that could not have formed naturally.

[1704.07263] Prior Indigenous Technological Species
https://arxiv.org/abs/1704.07263