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Archive for the ‘materials’ category: Page 197

Jul 23, 2020

Why This Stuff Costs $2700 Trillion Per Gram — Antimatter at CERN

Posted by in categories: materials, particle physics

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There’s a factory in Europe that makes antimatter! It’s the rarest, most expensive, and potentially the most dangerous material on earth. Scientists don’t know why this material is so rare. Anti-atoms took 72 years after we discovered antimatter to make. Why?

Continue reading “Why This Stuff Costs $2700 Trillion Per Gram — Antimatter at CERN” »

Jul 20, 2020

Scientists boost stability and efficiency of next-gen solar tech

Posted by in category: materials

Researchers from the Okinawa Institute of Science and Technology Graduate University (OIST) have created next-generation solar modules with high efficiency and good stability. Made using perovskites, these solar modules can maintain high performance for over 2000 hours. Their findings, reported 20 July 2020 in Nature Energy, have brightened prospects of commercialization.

Perovskites have the potential to revolutionize the solar technology industry. Flexible and lightweight, they promise more versatility than the heavy and rigid silicon-based cells currently dominating the market. But scientists must overcome some major hurdles before perovskites can be commercialized.

“There are three conditions that perovskites must meet: They must be cheap to produce, highly efficient and have a long lifespan,” said Professor Yabing Qi, head of the OIST Energy Materials and Surface Sciences Unit, who led this study.

Jul 20, 2020

A platinum and yttrium iron garnet-based structure produces a new magnetoresistance effect

Posted by in categories: materials, particle physics

In recent years, several research teams worldwide have been trying to develop a new class of devices known as spintronics or spin transport electronics. These devices can encode, store, process and transmit data using the spin of electrons in certain materials.

The operation of spintronics relies on magneto-transport effects, such as (GMR) and tunneling (TMR), which enable the transport of electrons through a given material in the form of a magnetic field. A device is generally made of two conductive ferromagnetic layers separated by a non-magnetic metal layer (i.e., a spin valve) or an insulator layer (i.e., a ).

Magneto-transport effects, which occur in a device’s spin valves and magnetic tunnel junctions, result in a relatively low resistance when the two magnetic layers are parallel and a relatively high resistance state when they are not. These effects are crucial to the functioning of many contemporary storage devices, including and magnetic random access memories (MRAMs).

Jul 20, 2020

Practical and versatile micro-patterning for organic electronics and photonics

Posted by in categories: computing, materials

Scientists have managed to draw at high resolution and speed, local patterns in organic semiconductor films used in optoelectronic and photonic applications. The new method enables the patterning of material characteristics and concomitant final properties, including molecular conformation, orientation, crystallinity and composition. The technique, published with open access in Nature Communications, has also been patented and industrial partners are sought for further co-development.

Bridging the gap between and the worldwide deployed silicon electronics requires new low cost and low energy consumption fabrication methods and technologies. This work represents a key enabling technology to accelerate the use of flexible and light-weight organic electronics and photonics to the level of silicon-based devices.

The microstructure and composition of organic semiconductors need to be tuned locally in order to optimize their properties, such as charge carrier mobility, electrical conductivity and light emission; and expand their functionalities for the practical upscaling of applications such as organic transistors (OFETs) and light emitting diodes (OLEDs), organic photovoltaics (OPV), organic thermoelectric generators (OTEGs), and organic photonic structures.

Jul 20, 2020

US20030067235A1 — Diamagnetic propulsion vehicle

Posted by in categories: materials, transportation

Omg levitating cars o,.o!


In this vehicle, the diamagnetic fields principles are applied to obtain a hovering and propulsion effect which makes low cost, friction free and zero pollutant emissions transport media. This is done using a special combination of electromagnetic and the natural diamagnetic susceptibility in all The physical effect of this is an air gap between the surface and the vehicle. The height of levitation has a direct relationship with the material used as floor surface; since all materials have diamagnetic susceptibility factors. Also, the power on the diamagnetic field is a key for the levitation and propulsion effect. All these factors make this prototype vehicle an easy maneuverable one, since there are almost no inertial forces in the system.

Jul 19, 2020

Scientists Create Room-Temperature All Liquid-Metal Batteries

Posted by in categories: energy, materials

A team from the Cockrell School of Engineering at the University of Texas at Austin have developed a new kind of battery that mixes the best of both worlds of liquid- and solid-state batteries. The design is the first all-liquid metal battery that can work at room temperature and is claimed to outperform lithium-ion batteries.

Liquid metal batteries are less susceptible to wearing out than solid batteries because dendrites don’t form and damage the components. The only downside is, most of these batteries need to be heated to at least 240°C (464°F) to keep the metals liquid and the equipment required to do that is bulky and energy-consuming.

For the study, published in the journal Advanced Materials, the UT team examined alloys that could remain liquid at useful temperatures. They decided to use a gallium-indium alloy for the cathode and a sodium-potassium alloy for the anode, which was able to stay liquid at 20°C (68°F). The researchers say it’s the lowest operating temperature ever recorded for a liquid-metal battery.

Jul 17, 2020

For The First Time Ever, Astronomers Have Witnessed a Black Hole ‘Blink’

Posted by in categories: cosmology, materials

Black holes don’t glow — in fact, they’re famous for doing the opposite. But if they’re actively devouring material from the space around them, that material can blaze like a billion X-ray Suns.

And for the first time, astronomers have now seen that blaze mysteriously snuffed out, before gradually returning to brightness.

The supermassive black hole is a beast clocking in at 19 million solar masses, powering a galactic nucleus 275 million light-years away, in a galaxy called 1ES 1927+654.

Jul 16, 2020

Superconductivity in metallic twisted bilayer graphene stabilized

Posted by in category: materials

Placing a single layer of tungsten diselenide in contact with twisted bilayer graphene enables superconductivity even for non-magic twist angles where insulating behavior is absent.

Jul 13, 2020

Underground CUPID-Mo Experiment in Search for Theorized ‘Neutrinoless’ Particle Process

Posted by in categories: materials, particle physics

Berkeley Lab researchers are part of an international team that reports a high-sensitivity measurement by underground CUPID-Mo experiment.

Nuclear physicists affiliated with the U.S. Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab) played a leading role in analyzing data for a demonstration experiment that has achieved record precision for a specialized detector material.

The CUPID-Mo experiment is among a field of experiments that are using a variety of approaches to detect a theorized particle process, called neutrinoless double-beta decay, that could revise our understanding of ghostly particles called neutrinos, and of their role in the formation of the universe.

Jul 13, 2020

Scientists demonstrate a new experiment in the search for theorized ‘neutrinoless’ proc

Posted by in categories: materials, particle physics

Nuclear physicists affiliated with the U.S. Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab) played a leading role in analyzing data for a demonstration experiment that has achieved record precision for a specialized detector material.

The CUPID-Mo experiment is among a field of experiments that are using a variety of approaches to detect a theorized particle process, called neutrinoless double-beta decay, that could revise our understanding of ghostly particles called neutrinos, and of their role in the formation of the universe.

The preliminary results from the CUPID-Mo experiment, based on the Berkeley Lab-led analysis of data collected from March 2019 to April 2020, set a new world-leading limit for the neutrinoless double-beta decay process in an isotope of molybdenum known as Mo-100. Isotopes are forms of an element that carry a different number of uncharged particles called neutrons in their atomic nuclei.