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Physicists have discovered a transparent, massless, and neutral "demon" particle that could help scientists understand superconductors better, according to a new study by researchers from the University of Illinois Urbana-Champaign. The study, published in the journal Nature on Wednesday, focused on the search for a particle first theorized by physicist David Pines in 1956. In solids, electrons act erratically, combining into collective units. If enough energy is input, the electrons can form plasmons - waves that act somewhat like a particle (also known as a quasiparticle) - if enough energy is input, although usually, the mass of solids is too...

A team of researchers claims to have created the first materials that conduct electricity perfectly at room temperature and ambient pressure, but many physicists are highly sceptical. Speaking to New Scientist, Hyun-Tak Kim at the College of William & Mary in Virginia says he will support anyone trying to replicate his team’s work. Superconductors are materials through which electricity can move without encountering any resistance, and so would significantly cut down the energy costs of electronics. But for over a century, researchers have been unable to make them work except under extreme conditions like very low temperatures and remarkably high...

Quantum machine - Inside the 30-meter tube. (ETH Zurich/Daniel Winkler) Albert Einstein wasn't entirely convinced about quantum mechanics, suggesting our understanding of it was incomplete. In particular, Einstein took issue with entanglement, the notion that a particle could be affected by another particle that wasn't close by. Experiments since have shown that quantum entanglement is indeed possible and that two entangled particles can be connected over a distance. Now a new experiment further confirms it, and in a way we haven't seen before. In the new experiment, scientists used a 30-meter-long tube cooled to close to absolute zero to run...

Scientists at the University of Rochester reported this week that they have taken a big leap toward creating a commercially viable superconductor that operates at room temperature and a low enough level of high pressure to be used in almost any technology that uses electric energy.

Thanks to Red Badger. Graphene is a strange material. Understanding its properties is both a fundamental question of science and a promising avenue for new technologies. A team of researchers from the Institute of Science and Technology Austria (ISTA) and the Weizmann Institute of Science has studied what happens when they layer four sheets of it on top of each other and how this can lead to new forms of exotic superconductivity. “Multilayered graphene has many promising qualities, ranging from widely tunable band structure and special optical properties to new forms of superconductivity—meaning being able to conduct electrical current without...

A visualization of the zero-energy electronic states – also known as a ‘Fermi surface’ – from the kagome material studied by MIT’s Riccardo Comin and colleagues. Credit: Comin Laboratory, MIT ************************************************************************** Work will aid design of other unusual quantum materials with many potential applications. MIT physicists and colleagues have discovered the “secret sauce” behind some of the exotic properties of a new quantum material that has transfixed physicists due to those properties, which include superconductivity. Although theorists had predicted the reason for the unusual properties of the material, known as a kagome metal, this is the first time that the...

A new discovery could help scientists to understand “strange metals,” a class of materials that are related to high-temperature superconductors and share fundamental quantum attributes with black holes. Scientists understand quite well how temperature affects electrical conductance in most everyday metals like copper or silver. But in recent years, researchers have turned their attention to a class of materials that do not seem to follow the traditional electrical rules. Understanding these so-called “strange metals” could provide fundamental insights into the quantum world, and potentially help scientists understand strange phenomena like high-temperature superconductivity. Now, a research team co-led by a Brown...

The Experimental Advanced Superconducting Tokamak (EAST) in Hefei in the east Chinese province of Anhui reports a new temperature record. At the end of last year, a plasma temperature of 70 million ° C could be maintained in the experimental nuclear fusion reactor for 1056 seconds, i.e. a good 17 minutes, reports the Institute for Plasma Physics at the Chinese Academy of Sciences (ASIPP). That is the longest time in which such a temperature could be kept constant. This creates a solid basis for further research into energy generation from nuclear fusion, writes the ASIPP. Its general director Prof. Yuntao...

The scientists have seen unexpected things in supercurrents—electricity that moves through materials without resistance, usually at super cold temperatures—that break symmetry and are supposed to be forbidden by the conventional laws of physics, said Jigang Wang, a professor of physics and astronomy at Iowa State University, a senior scientist at the U.S. Department of Energy's Ames Laboratory and the leader of the project. "The forbidden light gives us access to an exotic class of quantum phenomena—that's the energy and particles at the small scale of atoms—called forbidden Anderson pseudo-spin precessions," Perakis said. ... Wang's recent studies have been made possible...

(PhysOrg.com) -- Scientists from the U.S. Department of Energy's Lawrence Berkeley National Laboratory (Berkeley Lab) and the University of California at Berkeley have joined with researchers at Stanford University and the SLAC National Accelerator Laboratory to mount a three-pronged attack on one of the most obstinate puzzles in materials sciences: what is the pseudogap?A collaboration organized by Zhi-Xun Shen, a member of the Stanford Institute for Materials and Energy Science (SIMES) at SLAC and a professor of physics at Stanford University, used three complementary experimental approaches to investigate a single material, the high-temperature superconductor Pb-Bi2201 (lead bismuth strontium lanthanum copper-oxide)....

Scientists at The University of Manchester have discovered a new class of materials which have previously only existed in science fiction films and books. A team of British and Russian scientists led by Professor Geim have discovered a whole family of previously unknown materials, which are one atom thick and exhibit properties which scientists had never thought possible. Not only are they ultra-thin, but depending on circumstances they can also be ultra-strong, highly-insulating or highly-conductive, offering a wide range of unique properties for space-age engineers and designers to choose from. Professor Andre Geim said: "This discovery opens up practically infinite...

And it could be the key to understanding one of the biggest mysteries in physics today - high-temperature superconductors.An international team of scientists has announced the discovery of a new state of matter in a material that appears to be an insulator, superconductor, metal and magnet all rolled into one, saying that it could lead to the development of more effective high-temperature superconductors. Why is this so exciting? Well, if these properties are confirmed, this new state of matter will allow scientists to better understand why some materials have the potential to achieve superconductivity at a relativity high critical temperature...

Typically when referring to electrical current, an image of electrons moving through a metallic wire is conjured. Using the spin Seebeck effect (SSE), it is possible to create a current of pure spin (a quantum property of electrons related to its magnetic moment) in magnetic insulators. However, this work demonstrates that the SSE is not limited to magnetic insulators but also occurs in a class of materials known as paramagnets. Since magnetic moments within paramagnets do not interact with each other like in conventional ferromagnets, and thus do not hold their magnetization when an external magnetic field is removed, this...

The atom-thick sheet of carbon, graphene already has a number of amazing properties to it, including strength and electrical conductivity. As impressive its conductivity is though, superconductivity is still greater and has been observed with graphene, but not explained. Researchers at the SLAC National Accelerator Laboratory and Stanford University have now found how graphene and calcium become a superconductor.Called calcium intercalated graphite, or CaC6 is produced by interweaving calcium and graphite, which is a means of isolating sheets of graphene. About ten years ago it was discovered that this material could become superconducting, but neither the exact means nor...

Researchers at Japan's Tohoku University are making a bold claim: an entirely new state of matter. The team, led by Kosmas Prassides, says they've created what's called a Jahn-Teller metal by inserting rubidium, a strange alkali metal element, into buckyballs, a pure carbon structure which has a spherical shape from a series of interlocking polygons (think of the Epcot Center, but in microscopic size.) Advertisement - Continue Reading Below Buckyballs, which are somewhat related to other supermaterials like graphene and carbon nanotubes, are already known for their superconductive capabilities. Here, while combining buckyballs and rubidium, the researchers created a...

Surprising discovery may offer clues to emergence of high-temperature superconductivityUPTON, NY — Magnetic studies of ultrathin slabs of copper-oxide materials reveal that at very low temperatures, the thinnest, isolated layers lose their long-range magnetic order and instead behave like a “quantum spin liquid” — a state of matter where the orientations of electron spins fluctuate wildly. This unexpected discovery by scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory and collaborators at the Paul Scherrer Institute in Switzerland may offer support for the idea that this novel condensed state of matter is a precursor to the emergence of...

The 2011 Cold Fusion/Lattice-Assisted Nuclear Reactions Colloquium at the Massachusetts Institute of Technology — Part 2 (Report prepared by staff of JET Energy, Inc.) INFINITE ENERGY • ISSUE 99 • SEPTEMBER/OCTOBER 2011 The 2011 Lattice-Assisted Nuclear Reactions/Cold Fusion Colloquium at the Massachusetts Institute of Technology (Cambridge, Massachusetts) was held on Saturday, June 11 and Sunday, June 12, 2011. The meeting focused on the science and technology of cold fusion (CF) and lattice-assisted nuclear reactions (LANR). In 1989, the initial failures of cold fusion resulted from bad experiments, bad paradigm, materials issues, poor loadings and a poor appreciation of the...

MIT and Cold Fusion: A Special Report Compiled and written by Eugene F. Mallove, Sc.D. MIT Class of 1969, S.B. Aero/Astro Eng., 1970 S.M. Aero/Astro Eng. Editor-in-Chief, Infinite Energy Magazine President, New Energy Foundation, Inc. Introduction When on March 23, 1989 Drs. Martin Fleischmann and Stanley Pons announced that they had measured nuclear-scale excess energy from a palladium-heavy water electrochemical cell, and that they had also detected some preliminary evidence of nuclear signatures from their exotic energy-producing reactions, the world was in awe. Their famous afternoon press conference at the University of Utah, coming less than twelve hours before the...

Password guessing The U.S. intelligence community has launched a multi-year research project to develop a superconducting computer, awarding its first contracts to three major technology companies.IBM, Raytheon BBN and Northrop Grumman won the contracts, the Intelligence Advanced Research Projects Activity said Wednesday, without disclosing financial details.If it works, the Cryogenic Computer Complexity (C3) program could lead to a new generation of superconducting supercomputers."The energy demands of today's high-performance computers have become a critical challenge for the Intelligence Community that the C3 program aims to address," IARPA said in a statement. Such computers use massive amounts of energy.Competition from Europe, Japan...

http://news.softpedia.com/news/The-First-Test-That-Proves-General-Theory-of-Relativity-Wrong-20259.shtml According to Einstein's theory of general relativity, a moving mass should create another field, called gravitomagnetic field, besides its static gravitational field. This field has now been measured for the first time and to the scientists' astonishment, it proved to be no less than one hundred million trillion times larger than Einstein's General Relativity predicts. According to Einstein's theory of general relativity, a moving mass should create another field, called gravitomagnetic field, besides its static gravitational field. This field has now been measured for the first time and to the scientists' astonishment, it proved to be no less than...