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Researchers have created a virtual reality simulation of a supermassive black hole. In a recent paper in “Computational Astrophysics and Cosmology” they present their latest visualization. The simulation is based on the black hole in the center of our own Galaxy; Sagittarius A* (Sgr A*). Read this SpringerOpen blog to learn more. https://bit.ly/2S2Xh8p
For the first ever time, scientists have created a virtual reality (VR) simulation of Sagittarius A*- the black hole at the center of our galaxy. The simulation allows helps viewers to better visualize the phenomenon and study the black holes as well.
With the aim of creating a VR simulation of Sagittarius A*, scientists at Radboud University, The Netherlands and Goethe University, Germany come together and used an astrophysical model of Sagittarius A*. Through this model, they were able to capture an image series that then put together to create a 360-degree virtual reality simulation of the black hole.
The simulation can be seen using VR consoles. The most fascinating thing about this simulation is, it created one of the most realistic views of the direct surroundings of the black hole. Moreover, it is expected to help scientists to study the behavior of the black hole.
The next time you’re gazing out of the window in search of inspiration, keep in mind the material you’re looking through was forged inside the heart of an exploding ancient star.
An international team of scientists said Friday they had detected silica—the main component of glass—in the remnants of two distant supernovae billions of light years from Earth.
Researchers used NASA’s Spitzer Space Telescope to analyse the light emitted by the collapsing mega-cluster and obtain silica’s “fingerprint” based on the specific wavelength of light the material is known to emit.
Posted in climatology, cosmology | Leave a Comment on A ‘dark matter’ hurricane that we can’t see or hear is blasting past Earth, and it’s one of the universe’s biggest conundrums
I think aspects of our Universe are conscious. Dark matter or the æther perhaps. Stagnancy is death so change inherently means something is making decisions.
A new scientific concept has recently come to light, which scientists are calling “panpsychism.” Panpsychism says that the universe could be capable of consciousness, which could change everything.
For quite some time, scientists have been working to understand the universe, where it came from, and why we are here. However, they have often come up short until now. The scientist responsible for such a notion is Gregory Matloff, and his ideas are shocking, to say the least.
According to Matloff, a physicist at New York City College of Technology, in his recently published paper, humans could be like the rest of the universe, in substance and in spirit. Futurism reported that a “proto-consciousness field” could extend throughout all space. Basically, in lamens terms, the entire cosmos could be self-aware.
Remarkable rules have been detected in the apparent chaos of disequilibrium processes. Different systems behave identically in many ways, if they belong to the same “universality class.” This means that experiments can be carried out with quantum systems that are easy to handle in order to obtain precise information about systems that cannot be directly studied in the experiment—such as the Big Bang.
Some phenomena are so complicated that it is impossible to precisely calculate them. This includes large quantum systems, which consist of many particles, particularly when they are not in an equilibrium state, but changing rapidly. Such examples include the wild particle inferno that occurs in particle accelerators when large atoms collide, or conditions just after the Big Bang, when particles rapidly expanded and then cooled.
At TU Wien and Heidelberg University, remarkable rules have been detected in the apparent chaos of disequilibrium processes. This indicates that such processes can be divided into universality classes. Systems belonging to the same class behave identically in many ways. This means that experiments can be carried out with quantum systems that are easy to handle in order to obtain precise information about other systems that cannot be directly studied in the experiment. These findings have since been published in the journal Nature.
Wormholes — yawning gateways that could theoretically connect distant points in space-time — are usually illustrated as gaping gravity wells linked by a narrow tunnel.
But their precise shape has been unknown.
Now, however, a physicist in Russia has devised a method to measure the shape of symmetric wormholes — even though they have not been proven to exist — based on the way the objects may affect light and gravity. [8 Ways You Can See Einstein’s Theory of Relativity in Real Life].
