Menu

Blog

Page 8297

Oct 4, 2019

Producing dissipative coupling in hybrid quantum systems

Posted by in categories: particle physics, quantum physics

As quantum objects are susceptible to their surrounding environment, quantum coherence and quantum states can easily be destroyed due to the impact of external signals, which can include thermal noise and backscattered signals in the measurement circuit. Researchers have thus been trying to develop techniques to enable nonreciprocal signal propagation, which could help to block the undesired effects of backward noise.

In a recent study, members of the dynamic spintronics group at the University of Manitoba in Canada have proposed a new method to produce dissipative coupling in hybrid quantum systems. Their technique, presented in a paper published in Physical Review Letters, enables nonreciprocal signal propagation with a substantial isolation ratio and flexible controllability.

“Our recent work on nonreciprocity in cavity magnonics is grounded in a research area combining cavity spintronics and hybrid quantum systems, which holds promise for constructing new quantum information processing platforms,” Yi-Pu Wang, a postdoctoral researcher at the University of Manitoba who was involved in the study, told Phys.org.

Oct 4, 2019

Massive filaments fuel the growth of galaxies and supermassive black holes

Posted by in category: cosmology

An international group of scientists led by the RIKEN Cluster for Pioneering Research has used observations from the Multi Unit Spectroscopic Explorer (MUSE) at the ESO Very Large Telescope (VLT) in Chile and the Suprime-Cam at the Subaru telescope to make detailed observations of the filaments of gas connecting galaxies in a large, distant proto-cluster in the early universe.

Based on direct observations, they found that, in accordance with the predictions of the cold dark matter model of galaxy formation, the filaments are extensive, extending over more than 1 million parsecs—a parsec being just over three —and are providing the fuel for intense formation of stars and the growth of super within the proto-cluster.

The observations, which constitute a very detailed map of the filaments, were made on SSA22, a massive proto-cluster of located about 12 billion light years away in the constellation of Aquarius, making it a structure of the very early universe.

Oct 4, 2019

This is how a ‘fuzzy’ universe may have looked

Posted by in categories: cosmology, particle physics

Dark matter was likely the starting ingredient for brewing up the very first galaxies in the universe. Shortly after the Big Bang, particles of dark matter would have clumped together in gravitational “halos,” pulling surrounding gas into their cores, which over time cooled and condensed into the first galaxies.

Although dark matter is considered the backbone to the structure of the universe, scientists know very little about its nature, as the particles have so far evaded detection.

Now scientists at MIT, Princeton University, and Cambridge University have found that the early universe, and the very first galaxies, would have looked very different depending on the nature of dark matter. For the first time, the team has simulated what early galaxy formation would have looked like if dark matter were “fuzzy,” rather than cold or warm.

Oct 3, 2019

As Silicon Valley faces a tech reckoning, biologists point to the next big opportunity

Posted by in categories: biological, food, genetics

At SynBioBeta, entrepreneurs making plant-based foods and genetically engineered bacteria rallied to promote the idea that it’s biology’s century.

Oct 3, 2019

We Just Got The First Glimpse of The Mysterious Cosmic Web That Binds The Universe

Posted by in categories: cosmology, particle physics

After counting all the normal, luminous matter in the obvious places of the universe – galaxies, clusters of galaxies and the intergalactic medium – about half of it is still missing. So not only is 85 percent of the matter in the universe made up of an unknown, invisible substance dubbed “dark matter”, we can’t even find all the small amount of normal matter that should be there.

This is known as the “missing baryons” problem. Baryons are particles that emit or absorb light, like protons, neutrons or electrons, which make up the matter we see around us. The baryons unaccounted for are thought to be hidden in filamentary structures permeating the entire universe, also known as “the cosmic web”.

Continue reading “We Just Got The First Glimpse of The Mysterious Cosmic Web That Binds The Universe” »

Oct 3, 2019

A cyborg magician implanted 26 microchips and magnets in her body

Posted by in categories: computing, cyborgs, media & arts

L AS VEGAS — At a biohacker conference convened here the other day, panelists took to the stage, settled into their chairs, and launched into their slide decks. Not Anastasia Synn.

https://www.youtube.com/watch?v=cn-v5XUl35c#t=1h41m20s

With Frank Sinatra crooning “I’ve Got You Under My Skin” over the loudspeakers, Synn pulled out a giant needle and twisted it deeper and deeper into her left forearm as the music played on. It was only after finishing her routine, capped off by loud applause from the crowd of biohackers, that Synn sat down for a fireside chat about her work as a “cyborg magician.”

Continue reading “A cyborg magician implanted 26 microchips and magnets in her body” »

Oct 3, 2019

Secret Life of a Full-Time Cyborg

Posted by in categories: computing, cyborgs, wearables

Steve Mann invented a precursor to Google Glass in the 1990s—which he now uses almost 24/7. But “the father of wearable computing” has an ominous warning about where technology is taking us next.

Oct 3, 2019

Synopsis: Nuclear Spectroscopy Reveals New Shapes of Excited Nuclei

Posted by in category: nuclear energy

Cadmium nuclei take on multiple shapes at low excitation energies, a discovery that overturns a long-accepted tenet of nuclear structure.

Atomic nuclei take on excited states when they vibrate, rotate, or when their constituent nucleons exchange one nuclear shell for another. In nuclei with nearly filled nuclear shells, it has long been thought that low-energy excitations were due exclusively to different patterns of vibration around a spherical shape: only in rare, high-energy excitations were these nuclei expected to assume more exotic shapes. Now, Paul Garrett, of the University of Guelph in Canada, and colleagues have found that the lowest-energy excited states of cadmium-110 and cadmium-112—once considered textbook examples of spherical vibration—are instead due to the rotation of various nonspherical shapes. The result is also the best evidence to date that a stable nucleus like cadmium can assume multiple shapes—all previously studied nuclei with coexisting shapes have been radioactive.

Oct 3, 2019

A stirring new SpaceX animation of Starship launching shows how the rocket company plans to turn Texas into Earth’s interplanetary transport hub

Posted by in categories: Elon Musk, space travel

Following Elon Musk’s presentation about SpaceX’s Starship rocket, the company posted a 2-minute video showing how it’d refill the system in orbit.

Oct 3, 2019

NASA just shared a fascinating soundtrack of a Mars quake

Posted by in category: space

NASA’s InSight lander has picked up on some interesting rumblings on Mars, and the space agency shared them Tuesday in a blog post.

The spacecraft is equipped with an incredibly sensitive seismometer called the Seismic Experiment for Interior Structure (SEIS), which is designed to listen for marsquakes. By examining how seismic waves move through the planet’s interior, scientists hope to learn more about Mars’ deep inner structure.

Continue reading “NASA just shared a fascinating soundtrack of a Mars quake” »