New supercomputing calculations provide the first evidence that particles predicted by the theory of quark-gluon interactions but never before observed are being produced in heavy-ion collisions at the Relativistic Heavy Ion Collider, a facility that is dedicated to studying nuclear physics. These heavy strange baryons, containing at least one strange quark, still cannot be observed directly.
The first analysis of space dust collected by a special collector onboard NASA’s Stardust mission and sent back to Earth for study in 2006 suggests the tiny specks, which likely originated from beyond our solar system, are more complex in composition and structure than previously imagined. The analysis opens a door to studying the origins of the solar system and possibly the origin of life itself.
Thanks to a $1.5 million innovation award from the Gordon and Betty Moore Foundation, Rice Univ. physicist Emilia Morosan is embarking on a five-year quest to cook up a few unique compounds that have never been synthesized or explored. Morosan is no ordinary cook; her pantry includes metals, oxides and sulfides, and her recipes produce superconductors and exotic magnets.
A Univ. of Chicago-led team of researchers has developed a technique to record the quantum mechanical behavior of an individual electron contained within a nanoscale defect in diamond. Their technique uses ultrafast pulses of laser light, both to control the defect’s entire quantum state and observe how that single electron state changes over time.
What causes a proton to spin? This fundamental question has been a longstanding mystery in particle physics, although it was once thought that the answer would be fairly straightforward: The spin of a proton’s three subatomic particles, called quarks, would simply add up to produce its total spin.
Graphene may be tough, but those who handle it had better be tender. The environment surrounding the atom-thick carbon material can influence its electronic performance, according to researchers at Rice and Osaka universities who have come up with a simple way to spot contaminants.
From research stations drifting on ice floes to high-tech aircraft radar, scientists have been tracking the depth of snow that accumulates on Arctic sea ice for almost a century. Now that people are more concerned than ever about what is happening at the poles, research led by the Univ. of Washington and NASA confirms that snow has thinned significantly in the Arctic, particularly on sea ice in western waters near Alaska.
Researchers at Oregon State Univ. have developed a model that explains how geckos, as well as spiders and some insects, can run up and down walls, cling to ceilings and seemingly defy gravity with such effortless grace. This ability is a remarkable mechanism in the toes of geckos that uses tiny, branched hairs called “seta” that can instantly turn their stickiness on and off, and even “unstick” their feet without using any energy.
An international team of researchers has taken a significant step towards understanding the fundamental properties of the 2-D material silicene by showing that it can remain stable in the presence of oxygen. In a study published in 2D Materials, the researchers have shown that thick multi-layers of silicene can be isolated from parent material silicon and remain intact when exposed to air for at least 24 hrs.
Scientists hunting for life beyond Earth have discovered more than 1,800 planets outside our solar system, or exoplanets, in recent years, but so far, no one has been able to confirm an exomoon. Now, physicists from The Univ. of Texas at Arlington believe following a trail of radio wave emissions may lead them to that discovery.
To make a better optical fiber for transmitting laser beams, the first idea that comes to mind is probably not a nice long hydrogen bath. And yet, scientists have known for years that hydrogen can alter the performance of optical fibers, which are often used to transmit or even generate laser light in optical devices. Researchers at NIST have put this hydrogen “cure” to practical use.
Nature’s artistic and engineering skills are evident in proteins. Scientists at Rice Univ. have now employed their unique theories to show how the interplay between evolution and physics developed these skills. The team used computer models to show that the energy landscapes that describe how nature selects viable protein sequences over evolutionary timescales employ the same forces as those that allow proteins to fold.
Univ. College London scientists have discovered a new method to efficiently generate and control currents based on the magnetic nature of electrons in semiconducting materials, offering a new way to develop a new generation of electronic devices. One promising approach to developing new technologies is to exploit the electron’s tiny magnetic moment, or spin.
Performing systematic analyses of both known and imagined chemical compounds to find their key properties, Northwestern Univ. engineers have created a database that takes some of the guesswork out of designing new materials. Called the Open Quantum Materials Database (OQMD), it launched in November and is the largest database in the world of its kind, containing analyses of 285,780 compounds and growing.
For decades, scientists have been trying to use quantum systems for logical calculations, but implementing a system that manages superposition states is challenging. A team of researchers in Austria and Japan has now proposed a new architecture based on microscopic defects in diamond. They are convinced that the basic elements of their newly proposed architecture are better suited to be miniaturized, mass-produced and integrated on a chip.
Physicists at NIST have demonstrated a pas de deux of atomic ions that combines the fine choreography of dance with precise individual control. NIST’s ion duet is a component for a flexible quantum simulator that could be scaled up in size and configured to model quantum systems of a complexity that overwhelms traditional computer simulations.
Researchers at SLAC National Accelerator Laboratory have developed a laser-timing system that could allow scientists to take snapshots of electrons zipping around atoms and molecules. Taking timing to this new extreme of speed and accuracy at the Linac Coherent Light Source x-ray laser will make it possible to see the formative stages of chemical reactions.
By carefully controlling the position of an atomic-scale diamond defect within a volume smaller than what some viruses would fill, researchers have cleared a path toward better quantum computers and nanoscale sensors. These diamond defects are attractive candidates for qubits, the quantum equivalent of a computing bit, and accurate positioning is key to using them to store and transmit information.
The million-mile-per-hour solar wind pushed out by the Sun inflates a giant bubble in the interstellar medium called the heliosphere, which envelops the Earth and the other planets. At the 40th International Committee on Space Research (COSPAR) Scientific Assembly in Moscow this week, scientists highlighted an impressive list of achievements in researching the outer heliosphere, which barely registered as a field of research ten years ago.
Magnetic resonance imaging (MRI) is best-known for its use in medicine, but because MRI operates by quantum principles it translates to other quantum systems. Recently, physicists at the Joint Quantum Institute have executed an MRI-like diagnostic on a crystal of interacting quantum spins. The technique reveals many features of their system, such as the spin-spin interaction strengths and the energies of various spin configurations.
Graphene has become a focus of research on a variety of potential uses. Now researchers at Massachusetts Institute of Technology have found a way to control how the material conducts electricity by using extremely short light pulses, which could enable its use as a broadband light detector.
Using a new method to track the electrochemical reactions in a common electric vehicle battery material under operating conditions, scientists at Brookhaven National Laboratory have revealed new insight into why fast charging inhibits this material's performance. The study also provides the first direct experimental evidence to support a particular model of the electrochemical reaction.
More than 42 million years of natural selection have turned hummingbirds into some of the world's most energetically efficient flyers, particularly when it comes to hovering in place. Humans, however, are gaining ground quickly. A new study led by David Lentink, an assistant professor of mechanical engineering at Stanford, reveals that the spinning blades of micro-helicopters are about as efficient at hovering as the average hummingbird.
Researchers in Austria have performed the first separation of a particle from one of its properties. The study showed that in an interferometer a neutron’s magnetic moment could be measured independently of the neutron itself, thereby marking the first experimental observation of a new quantum paradox known as the “Cheshire cat”.
A new study has investigated the effects of small but finite inertia on the propulsion of micro- and nano-scale swimming machines. Scientists have found that the direction of propulsion made possible by such inertia is opposite to that induced by a viscoelastic fluid. The findings could help to optimize the design of swimming machines to improve their mobility in medical applications.