Are electrons truly round? More specifically, is the electron’s charge between its poles uniform? A group at JILA has tackled this difficult question and has developed a method of spinning electric and magnetic fields around trapped molecular ions to measure the tiny electrons. They haven’t yet matched other electric dipole moment measurement techniques, but eventually the new method should surpass them.
High-temperature superconductors exhibit a frustratingly varied catalog of odd behavior, such as...
Scientists from NIST and Sandia National Laboratories have added something new to a family of...
A multinational team led by Chinese researchers in collaboration with U.S. and European partners has successfully demonstrated a novel technique for suppressing instabilities that can cut short the life of controlled fusion reactions. The team combined the new technique with a method that Princeton Plasma Physics Laboratory has developed for protecting the walls that surround the hot, charged plasma gas that fuels fusion reactions.
A collaboration of physicists and engineers has found a new way to control electron spins not with a magnetic field but with a mechanical oscillator. This demonstration of electron spin resonance that’s “shaken, not stirred” showed that an oscillator can drive the transitions of electron spins within defects commonly found in the crystal lattice of a diamond.
A team working at the SACLA x-ray Free-Electron Laser in Japan has, for the first time, succeeded in generating ultra-bright, two-color x-ray laser pulses in the hard x-ray region. These light pulses have different wavelengths whose time separation can be adjusted with attosecond accuracy. They could be powerful tools for investigating the structure of matter and the dynamics of ultrafast physical processes and chemical reactions.
Quantum entanglement, a perplexing phenomenon of quantum mechanics that Albert Einstein once referred to as “spooky action at a distance,” could be even spookier than Einstein perceived. A team of physicists believe the phenomenon might be intrinsically linked with wormholes, hypothetical features of space-time that in popular science fiction can provide a much-faster-than-light shortcut from one part of the universe to another.
Research has shed new light on the properties of neutron stars, super dense stars that form when a large star explodes and collapses into itself. Writing in Nature, the team describes a newly discovered process that happens within the star's crust, located just below the surface. Until now, scientists thought that nuclear reactions within the crust contributed to the heating of the star's surface.
They are the coldest objects in the universe and are so fragile that even a single photon can heat and destroy them. Known as Bose-Einstein condensates (BECs) and consisting of just a cluster of atoms, it has up until now been impossible to measure and control these remarkable forms of matter simultaneously.
Professor Ken Naitoh of Waseda Univ.'s Faculty of Science and Engineering has discovered a new compressive combustion principle that could yield engines with a much higher level of thermal efficiency: up to 60% or more in applications including automobiles, power generation and aircraft.
In a new effort to understand magnetism, a group of Hamburg Centre for Ultrafast Imaging researchers created “mimic” magnets by controlling quantum matter waves made of rubidium atoms. Under well-defined conditions made possible with the help of supercomputers, these artificially created magnets can be studied with clarity and then give a fresh perspective on long-standing riddles.
In materials science, electric and magnetic effects have usually been studied separately. There are, however, extraordinary materials called “multiferroics”, in which electric and magnetic excitations are closely linked. Scientists in Austria have now shown in an experiment that magnetic properties and excitations can be influenced by an electric voltage.
Stuck inside on a rainy, dreary day in France, two physicists and an engineer stumbled on a television program about whirling dervishes. The film caused them to discuss structures with conical symmetry, or rotating flexible structures with a conical shape. Their thoughts have become the basis for a recent technical paper, which uses understandings of Coriolis force to develop simple explanatory equations.
Suggesting that quantum computers might benefit from losing some data, physicists at NIST have entangled—linked the quantum properties of—two ions by leaking judiciously chosen information to the environment. The NIST experiments used two beryllium ions as quantum bits (qubits) to store quantum information and two partner magnesium ions, which were cooled with three ultraviolet laser beams to release heat.
The Q-factor is a dimensionless parameter that describes how under-damped an oscillator or resonator is, and this has so far been limited by coupling the device to a physical contact for support. Researchers in Spain, however, have used optically levitated objects that do not suffer from clamping forces to achieve the highest force sensitivity ever observed with a nanomechanical resonator.
Scientists in Israel have taken a quantum leap toward understanding the phenomenon known as superconductivity: They have created the world’s smallest SQUID, a device used to measure magnetic fields, which has broken the world record for sensitivity and resolution.
In April, a bright flash of light burst from near the constellation Leo. Originating billions of light years away, this explosion of light, called a gamma ray burst, has now been confirmed as the brightest gamma ray burst ever observed. Astronomers around the world were able to view the blast in unprecedented detail and observe several aspects of the event. The data could lead to a rewrite of standard theories on how gamma ray bursts work.
Spontaneous bursts of light from a solid block illuminate the unusual way interacting quantum particles behave when they are driven far from equilibrium. The discovery by Rice Univ. scientists of a way to trigger these flashes may lead to new telecommunications equipment and other devices that transmit signals at picosecond speeds.
Most traditional synchrotron x-ray devices are gigantic and costly, available only at a few sites around the world. Using a compact but powerful laser, a research team at the Univ. of Nebraska-Lincoln has developed a new way to generate synchrotron x-rays that could greatly expand the availability of this technique for researchers.
A single layer of tin atoms could be the world’s first material to conduct electricity with 100% efficiency at the temperatures that computer chips operate, according to a team of theoretical physicists led by researchers from SLAC National Accelerator Laboratory and Stanford Univ.
In our universe there are particle accelerators 40 million times more powerful than the Large Hadron Collider at CERN. Scientists don’t know what these cosmic accelerators are or where they are located, but new results being reported from IceCube, the neutrino observatory buried at the South Pole, may show the way. These new results should also erase any doubts as to IceCube’s ability to deliver on its promise.
A new technique that allows curved surfaces to appear flat to electromagnetic waves has been developed by scientists in England. The discovery could hail a step-change in how antennas are tailored to each platform, which could be useful to a number of industries that rely on high performance antennas for reliable and efficient wireless communications.
In a recent study presented at the Supercomputing Conference SC13 in Denver that may earn them the Gordon Bell Prize, physicists from Germany have simulated the motion of billions of electrons within astrophysical plasma jets and calculated the light they emit. Tracking the movements of nearly a hundred billion particles required the help of a high-performance computer.
Cooling systems generally rely on water pumped through pipes to remove unwanted heat. Now, researchers at Massachusetts Institute of Technology and in Australia have found a way of enhancing heat transfer in such systems by using magnetic fields, a method that could prevent hotspots that can lead to system failures. The system could also be applied to cooling everything from electronic devices to advanced fusion reactors, they say.
An instrument on NASA's Lunar Reconnaissance Orbiter (LRO) has learned more than ever before about the high-energy hazards at and around the moon. These dangers are serious but manageable, and human exploration missions will rely on these measurements to know how much radiation to expect in deep space and how best to shield against it.
Understanding superconductivity has proved to be one of the most persistent problems in modern physics. Scientists have struggled for decades to develop a cohesive theory of superconductivity, largely spurred by the game-changing prospect of creating a superconductor that works at room temperature, but it has proved to be a tremendous tangle of complex physics.
Ferroelectric materials are known for their ability to spontaneously switch polarization when an electric field is applied. An Oak Ridge National Laboratory-led team took advantage of this property to draw areas of switched polarization called domains on the surface of a ferroelectric material. To the researchers’ surprise, the domains began forming complex and unpredictable patterns that the researchers say should not be possible.
Rare anywhere, thundersnow is sometimes heard during the lake-effect snowstorms of the Great Lakes. The interaction of clouds and ice pellets inside these storms generates a charge, with lightning and thunder the result. But how to catch thundersnow in action? Doppler-on-Wheels, a system used for other types of storms, will try to find them this winter.
- Page 1