This image shows observations of a newly discovered galaxy core dubbed GOODS-N-774, taken by the NASA/ESA Hubble Space Telescope’s Wide Field Camera 3 and Advanced Camera for Surveys. The core is marked by the box inset, overlaid on a section of the Hubble GOODS-N, or GOODS North, field (Great Observatories Origins Deep Survey). (Credit: NASA, ESA)
via phys.org
The moment of detonation of a Type 1a supernova is modeled. This situation arises when a white dwarf star has accreted mass from a binary partner to a point when gravitational forces overcome the outward electron degeneracy pressure. The star collapses and it is thought that carbon fusion is initiated in the core, creating a supernova. (Credit: Argonne National Laboratory)
White Dwarf No More – The Type 1a supernova proceeds in the simulation, ripping through the white dwarf star. The star is completely destroyed. Around 1-2 × 1044 Joules of energy is released from Type 1a supernovae, ejecting matter and shock waves traveling at velocities of 3-12,000 miles per second (approximately 2-7% the speed of light). (Credit: Argonne National Laboratory)
Complex Fluid Mechanics – Detailed visualizations of the nuclear combustion inside a supernova. The calculations are based on fluid mechanics, showing how the explosion rips through the star. (Credit: Argonne National Laboratory)
Cosmic rays can help scientists do something no one else can: safely image the interior of the nuclear reactors at the Fukushima Daiichi plant. In the Los Alamos National Laboratory, postdoc Elena Guardincerri, right, and undergraduate research assistant, Shelby Fellows, prepare a lead hemisphere inside a muon tomography machine. (Credit: Los Alamos National Laboratory, Tuttle)
via symmetrymagazine
This artist’s impression shows a possible mechanism for a Type Ia supernova. Astronomers have shown that dead stars known as white dwarfs can re-ignite and explode as supernovas. (Credit: NASA)via bbc
llustration of data from the Spitzer Space Telescope, showing the massive increase in dust around the star NGC 2547-ID8, thought to be the result of an asteroid collision. Image (Credit: NASA/JPL-Caltech/University of Arizona)
via americaspace
A plot showing a spin up, spin down, and the resulting spin polarized population of electrons. Inside a spin injector, the polarization is constant, while outside the injector, the polarization decays exponentially to zero as the spin up and down populations go to equilibrium. (Credit SA3.0)
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View of a thin-disc laser. Its geometry ensures more stable operation at higher powers than is possible with conventional solid-state lasers. (Credit: Thomas Metzger)
via phys.org
The Hubble Space Telescope finished another step in a important mission, looking for water in the milky way. The results so far are a bit surprising, with three exoplanets (planets outside the solar system) coming up short in their water supplies. (Credit: Greg Bacon)
via inquisitr
Rosetta imaged its target comet, Comet 67P/Churyumov-Gerasimenko, from about 3,417 miles (5,500 kilometers) away. The “neck” of the comet appears to be brighter than the rest of the nucleus. (Credit: ESA/Rosetta/MPS for OSIRIS Team MPS/UPD/LAM/IAA/SSO/INTA/UPM/DASP/IDA)
via universetoday
The atomic layers of the topological insulator bismuth selenide are visible in this high-resolution electron microscope image. (Credit: Samarth lab, Penn State University)
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Proposals for two particle accelerators could see the country aim to become the collider capital of the world. View of the LHC tunnel sector 3-4. (Credit: Maximilien Brice (CERN))
via scientificamerican
Fig. 1. Left: Limits on the dark-matter particle mass as a function of the effective interaction scale from the associated production of the particle with a top-quark pair. Fig. 2. Right: The limits set on the dark-matter particle mass from the search for invisible Higgs-boson decays compared with those from direct-detection experiments. (Credit: CMS)
via cerncourier
One approach of making computers faster relies on quantum dots, a kind of artificial atom, easily controlled by applying an electric field. A new study demonstrates that changing the coupling of three coherently coupled quantum dots with electrical impulses can help better control them. (Credit: Tooski, S. B. et al.)
via sciencecodex
There’s nothing like a Star Trek reference (yay Tribbles!) to help explain complex stuff like quantum computing. (Credit: Microsoft, Michael-Freedman)
via gigaom
