This super strong stitching system helps surgeons close up major gashes in the skin đ„.
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Astronomers from the United States and South Korea have made the first high-resolution, radio telescope observations of the molecular clouds within a massive star-forming region of the outer Milky Way.
âThis region is behind a nearby cloud of dust and gas,â said Charles Kerton, an associate professor of physics and astronomy at Iowa State University and a member of the study team. âThe cloud blocks the light and so we have to use infrared or radio observations to study it.â
The Milky Way region is called CTB 102. Itâs about 14,000 light years from Earth. Itâs classified as an HII region, meaning it contains clouds of ionizedâchargedâhydrogen atoms. And, because of its distance from Earth and the dust and gas in between, it has been difficult to study.
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Researchers hoping to better interpret data from the detection of gravitational waves generated by the collision of binary black holes are turning to the public for help.
West Virginia University assistant professor Zachariah Etienne is leading what will soon become a global volunteer computing effort. The public will be invited to lend their own computers to help the scientific community unlock the secrets contained in gravitational waves observed when black holes smash together.
LIGOâs first detection of gravitational waves from colliding black holes in 2015 opened a new window on the universe, enabling scientists to observe cosmic events spanning billions of years and to better understand the makeup of the Universe. For many scientists, the discovery also fueled expansion of efforts to more thoroughly test the theories that help explain how the universe worksâwith a particular focus on inferring as much information as possible about the black holes prior to their collision.
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A team has proposed using nanobots to create the âinternet of thoughtsâ, where instant knowledge could be downloaded just by thinking it.
An international team of scientists led by members of UC Berkeley and the US Institute for Molecular Manufacturing predicts that exponential progress in nanotechnology, nanomedicine, artificial intelligence (AI) and computation will lead this century to the development of a human âbrain-cloud interfaceâ (B-CI).
Writing in Frontiers in Neuroscience, the team said that a B-CI would connect neurons and synapses in the brain to vast cloud computing networks in real time.
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Scientists believe that time is continuous, not discreteâroughly speaking, they believe that it does not progress in âchunks,â but rather âflows,â smoothly and continuously. So they often model the dynamics of physical systems as continuous-time âMarkov processes,â named after mathematician Andrey Markov. Indeed, scientists have used these processes to investigate a range of real-world processes from folding proteins, to evolving ecosystems, to shifting financial markets, with astonishing success.
However, invariably a scientist can only observe the state of a system at discrete times, separated by some gap, rather than continually. For example, a stock market analyst might repeatedly observe how the state of the market at the beginning of one day is related to the state of the market at the beginning of the next day, building up a conditional probability distribution of what the state of the second day is given the state at the first day.
In a pair of papers, one appearing in this weekâs Nature Communications and one appearing recently in the New Journal of Physics, physicists at the Santa Fe Institute and MIT have shown that in order for such twoâtime dynamics over a set of âvisible statesâ to arise from a continuous-time Markov process, that Markov process must actually unfold over a larger space, one that includes hidden states in addition to the visible ones. They further prove that the evolution between such a pair of times must proceed in a finite number of âhidden timestepsâ, subdividing the interval between those two times. (Strictly speaking, this proof holds whenever that evolution from the earlier time to the later time is noise-freeâsee paper for technical details.)
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Two European theoretical physicists have shown that it may be possible to build a near-perfect, entangled quantum battery. In the future, such quantum batteries might power the tiniest of devices â or provide power storage that is much more efficient than state-of-the-art lithium-ion battery packs.
To understand the concept of quantum batteries, we need to start (unsurprisingly) at a very low level. Today, most devices and machines that you interact with are governed by the rules of classical mechanics (Newtonâs laws, friction, and so on). Classical mechanics are very accurate for larger systems, but they fall apart as we begin to analyze microscopic (atomic and sub-atomic) systems â which led to a new set of laws and theories that describe quantum mechanics.
In recent years, as our ability to observe and manipulate quantum systems has grown â thanks to machines such as the Large Hadron Collider and scanning tunneling electron microscopes â physicists have started theorizing about devices and machines that use quantum mechanics, rather than classical. In theory, these devices could be much smaller, more efficient, or simply act in rather unsurprising ways. In this case, Robert Alicki of the University of Gdansk in Poland, and Mark Fannes of the University of Leuven in Belgium, have defined a battery that stores and releases energy using quantum mechanics.
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