Steven Yeun: Dazed & Confused September, 2018 [Part 1]
One Nice Bug Per Day
will byers stan first human second
$LAYYYTER

Love Begins
ojovivo

Andulka

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PR's Tumblrdome
noise dept.
macklin celebrini has autism

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Lint Roller? I Barely Know Her
YOU ARE THE REASON
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Jules of Nature
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Three Goblin Art
DEAR READER
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@lovingheem
Steven Yeun: Dazed & Confused September, 2018 [Part 1]
Super Junior is back with the repackaged album, “Replay” and we are loving the title track “Lo Siento.” East meets West as the group teamed up with Latin artist Leslie Grace and Grammy award-winning American record producer Play-N-Skillz. The album is composed of 14 tracks including new additional songs “Me & U,” “Hug,” and the pre-released SM Station song, “Super Duper.” The digital version of the album also consists of another version of Lo Siento featuring KARD members Somin and Jiwoo. Watch their comeback stage on Mnet’s M Countdown here.
He has no idea how rare you are.
Two Night Stand (2014), Dir. Max Nichols (via thequotejournals)
She will grow and prosper (Source: http://ift.tt/2Ccwkr2)
Def thought that was bread
tbh if this happened to me idk if i’d even be mad that’s funny
What is Gravitational Lensing?
A gravitational lens is a distribution of matter (such as a cluster of galaxies) between a distant light source and an observer, that is capable of bending the light from the source as the light travels towards the observer. This effect is known as gravitational lensing, and the amount of bending is one of the predictions of Albert Einstein’s general theory of relativity.
This illustration shows how gravitational lensing works. The gravity of a large galaxy cluster is so strong, it bends, brightens and distorts the light of distant galaxies behind it. The scale has been greatly exaggerated; in reality, the distant galaxy is much further away and much smaller. Credit: NASA, ESA, L. Calcada
There are three classes of gravitational lensing:
1° Strong lensing: where there are easily visible distortions such as the formation of Einstein rings, arcs, and multiple images.
Einstein ring. credit: NASA/ESA&Hubble
2° Weak lensing: where the distortions of background sources are much smaller and can only be detected by analyzing large numbers of sources in a statistical way to find coherent distortions of only a few percent. The lensing shows up statistically as a preferred stretching of the background objects perpendicular to the direction to the centre of the lens. By measuring the shapes and orientations of large numbers of distant galaxies, their orientations can be averaged to measure the shear of the lensing field in any region. This, in turn, can be used to reconstruct the mass distribution in the area: in particular, the background distribution of dark matter can be reconstructed. Since galaxies are intrinsically elliptical and the weak gravitational lensing signal is small, a very large number of galaxies must be used in these surveys.
The effects of foreground galaxy cluster mass on background galaxy shapes. The upper left panel shows (projected onto the plane of the sky) the shapes of cluster members (in yellow) and background galaxies (in white), ignoring the effects of weak lensing. The lower right panel shows this same scenario, but includes the effects of lensing. The middle panel shows a 3-d representation of the positions of cluster and source galaxies, relative to the observer. Note that the background galaxies appear stretched tangentially around the cluster.
3° Microlensing: where no distortion in shape can be seen but the amount of light received from a background object changes in time. The lensing object may be stars in the Milky Way in one typical case, with the background source being stars in a remote galaxy, or, in another case, an even more distant quasar. The effect is small, such that (in the case of strong lensing) even a galaxy with a mass more than 100 billion times that of the Sun will produce multiple images separated by only a few arcseconds. Galaxy clusters can produce separations of several arcminutes. In both cases the galaxies and sources are quite distant, many hundreds of megaparsecs away from our Galaxy.
Gravitational lenses act equally on all kinds of electromagnetic radiation, not just visible light. Weak lensing effects are being studied for the cosmic microwave background as well as galaxy surveys. Strong lenses have been observed in radio and x-ray regimes as well. If a strong lens produces multiple images, there will be a relative time delay between two paths: that is, in one image the lensed object will be observed before the other image.
As an exoplanet passes in front of a more distant star, its gravity causes the trajectory of the starlight to bend, and in some cases results in a brief brightening of the background star as seen by a telescope. The artistic concept illustrates this effect. This phenomenon of gravitational microlensing enables scientists to search for exoplanets that are too distant and dark to detect any other way.Credits: NASA Ames/JPL-Caltech/T. Pyle
Explanation in terms of space–time curvature
Simulated gravitational lensing by black hole by: Earther
In general relativity, light follows the curvature of spacetime, hence when light passes around a massive object, it is bent. This means that the light from an object on the other side will be bent towards an observer’s eye, just like an ordinary lens. In General Relativity the speed of light depends on the gravitational potential (aka the metric) and this bending can be viewed as a consequence of the light traveling along a gradient in light speed. Light rays are the boundary between the future, the spacelike, and the past regions. The gravitational attraction can be viewed as the motion of undisturbed objects in a background curved geometry or alternatively as the response of objects to a force in a flat geometry.
A galaxy perfectly aligned with a supernova (supernova PS1-10afx) acts as a cosmic magnifying glass, making it appear 100 billion times more dazzling than our Sun. Image credit: Anupreeta More/Kavli IPMU.
To learn more, click here.
What are white dwarfs?
Some curiosities about white dwarfs, a stellar corpse and the future of the sun.
Where a star ends up at the end of its life depends on the mass it was born with. Stars that have a lot of mass may end their lives as black holes or neutron stars.
A white dwarf is what stars like the Sun become after they have exhausted their nuclear fuel. Near the end of its nuclear burning stage, this type of star expels most of its outer material, creating a planetary nebula.
In 5.4 billion years from now, the Sun will enter what is known as the Red Giant phase of its evolution. This will begin once all hydrogen is exhausted in the core and the inert helium ash that has built up there becomes unstable and collapses under its own weight. This will cause the core to heat up and get denser, causing the Sun to grow in size.
It is calculated that the expanding Sun will grow large enough to encompass the orbit’s of Mercury, Venus, and maybe even Earth.
A typical white dwarf is about as massive as the Sun, yet only slightly bigger than the Earth. This makes white dwarfs one of the densest forms of matter, surpassed only by neutron stars and black holes.
The gravity on the surface of a white dwarf is 350,000 times that of gravity on Earth.
White dwarfs reach this incredible density because they are so collapsed that their electrons are smashed together, forming what is called “degenerate matter.” This means that a more massive white dwarf has a smaller radius than its less massive counterpart. Burning stars balance the inward push of gravity with the outward push from fusion, but in a white dwarf, electrons must squeeze tightly together to create that outward-pressing force. As such, having shed much of its mass during the red giant phase, no white dwarf can exceed 1.4 times the mass of the sun.
While many white dwarfs fade away into relative obscurity, eventually radiating away all of their energy and becoming a black dwarf, those that have companions may suffer a different fate.
If the white dwarf is part of a binary system, it may be able to pull material from its companion onto its surface. Increasing the mass can have some interesting results.
One possibility is that adding more mass to the white dwarf could cause it to collapse into a much denser neutron star.
A far more explosive result is the Type 1a supernova. As the white dwarf pulls material from a companion star, the temperature increases, eventually triggering a runaway reaction that detonates in a violent supernova that destroys the white dwarf. This process is known as a single-degenerate model of a Type 1a supernova.
If the companion is another white dwarf instead of an active star, the two stellar corpses merge together to kick off the fireworks. This process is known as a double-degenerate model of a Type 1a supernova.
At other times, the white dwarf may pull just enough material from its companion to briefly ignite in a nova, a far smaller explosion. Because the white dwarf remains intact, it can repeat the process several times when it reaches the critical point, briefly breathing life back into the dying star over and over again.
Image credit: www.aoi.com.au, NASA, Wikimedia Commons, Fsgregs, quora.com, quora.com, NASA’s Goddard Space Flight Center, S. Wiessinger, ESO, ESO, Chandra X-ray Observatory
Source: NASA, NASA, space.com
What is Quantum Physics?
Quantum physics is a branch of science that deals with discrete, indivisible units of energy called quanta as described by the Quantum Theory. There are five main ideas represented in Quantum Theory:
Energy is not continuous, but comes in small but discrete units.
The elementary particles behave both like particles and like waves.
The movement of these particles is inherently random.
It is physically impossible to know both the position and the momentum of a particle at the same time. The more precisely one is known, the less precise the measurement of the other is
The atomic world is nothing like the world we live in.
While at a glance this may seem like just another strange theory, it contains many clues as to the fundamental nature of the universe and is more important than even relativity in the grand scheme of things (if any one thing at that level could be said to be more important than anything else). Furthermore, it describes the nature of the universe as being much different then the world we see. As Niels Bohr said, “Anyone who is not shocked by quantum theory has not understood it.”
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Thank you for making this night memorable for PH Boices, CNBLUE! 💙 #cnblue #cnblueinmanila #betweenus #betweenusinmanila #kpop #yonghwa #minhyuk #jonghyun #jungshin (at Smart Araneta Coliseum)
Mulat. #PaaralanPalaruan (at University of the Philippines)
Marco Jose's #HisPossessiveWays is already available on different bookstores and newsstands nationwide. Get your own copy now to meet Greg and Raisse! ❤️📚 To read more of Marco Jose's stories, visit http://wattpad.com/user/SiMarcoJoseAko. 🔗 #Wattpad #WattpadPH #books #MarcoJose #SiMarcoJoseAko #PopFiction #SummitMedia
Kilig vibes will be on this Summer 2017 as Kathryn Bernardo and Daniel Padilla return to the big screen with the romantic comedy film, “Can’t Help Falling In Love.” The tandem reunites with Mae Cruz-Alviar who also directed their 2015 hit movie “Crazy Beautiful You.” Watch Dos and Gab on the first teaser here. Star Cinema also came out with an extended teaser with scenes shot from the Queen City of the South! Daniel sings his own rendition of Can’t Help Falling In Love With You for the film’s soundtrack. You can watch the music video here.
Can’t Help Falling In Love is slated to be released on April 15. So if you’re looking for something to do this Black Saturday, bring your loved ones to the nearest cinema and have a date with KathNiel!
Spread blue hearts on SNS with the hashtag #CHFIL! 💙
Check out the music video for Imagine Dragons’ latest single, “Believer”