Lifeboat Foundation

An international team of researchers led by scientists at Princeton University has found that a magnetic material at room temperature enables electrons to behave counterintuitively, acting collectively rather than as individuals. Their collective behavior mimics massless particles and anti-particles that coexist in an unexpected way and together form an exotic loop-like structure.

The key to this behavior is topology—a branch of mathematics that is already known to play a powerful role in dictating the behavior of electrons in crystals. Topological materials can contain massless particles in the form of light, or photons. In a topological crystal, the electrons often behave like slowed-down light yet, unlike light, carry electrical charge.

Topology has seldom been observed in magnetic materials, and the finding of a magnetic topological material at room temperature is a step forward that could unlock new approaches to harnessing topological materials for future technological applications.

The electromagnetic field generator includes a shell, an electrostatic generator, a power plant, a thermoelectric generator, and an electric motor. The shell has embedded polycrystalline ferroelectric ceramic material which is polarized such that the ceramic material exhibits strong Piezoelectric Effect properties thus inducing high frequency vibrations. The shell may be further doped with radioactive elements which under high frequency vibrations induce gamma ray emission. The electrostatic generator is for charging up the shell and is disposed within the shell. The power plant is to generate thermal power, and is disposed within the sphere. The thermoelectric generator is to convert the thermal power generated by the power plant to electrical energy. The electric motor powered by the electrical energy generated by the thermoelectric generator, and supplies input voltage such that the shell spins at high angular speeds, vibrates at high frequencies, and generates an electromagnetic field.

Concrete could provide humans in space with better protection from radiation and extreme temperatures than many other materials.

O.o.

SUITA, Osaka — A group of researchers at Kansai University here has developed a material with significant germ-killing effects by copying the structure of cicada wings.

блядь! An explosion at Russia’s State Research Centre of Virology and Biotechnology (Vector) resulted in a fire, glass blown out throughout the building, and one worker suffering third degree burns on Monday, according to the Bulletin of Atomic Scientists. Vector is one of the only two places in the world where live smallpox virus samples are officially stored, as well as retains stocks of other deadly pathogens including the Ebola virus and anthrax spores.

According to the state-run TASS news agency, Koltsovo city head administrator Nikolai Krasnikov said that the blast occurred during scheduled repair work, blowing out glass in the building and starting a 30 square meter fire. Various reports have indicated the incident started with a gas explosion. However, Krasnikov emphasized that no biohazardous materials were stored where the explosion and blaze occurred, and that there is no threat to the general population. The Vector building in question did not suffer structural damage, Krasnikov added, while the worker is in “intensive” condition.

Anders Ohlsson Delivery Manager at Sandvik Additive Manufacturing, shared his excitement for the new process in the Sandvik press release stating, “On seeing its potential, we began to wonder what else would be possible from 3D-printing complex shapes in a material that is three times stiffer than steel, with heat conductivity higher than copper, the thermal expansion close to Invar – and with a density close to aluminum.”

Today we are taking a look at how Sandvik created the first-ever 3D printed diamond composite.

Sub-nanometre resolution in 3D position measurements of light-emitting molecules has been achieved by physicists in Germany. Jörg Enderlein and colleagues at the University of Göttingen achieved the result by replacing metal films used in previous super-resolution techniques with single layers of graphene. Their innovation could allow researchers in a wide variety of fields to measure molecular positions to unprecedented degrees of accuracy.

Recently, the technique of single-molecule localization super-resolution microscopy (SMLM) has become an incredibly useful tool for researchers in fields ranging from fundamental physics to medical research. By analysing images of single light-emitting molecules, researchers can pinpoint the positions of their centres to within single atomic widths. However, SMLM faces one significant shortcoming: it can only locate molecules in 2D, giving no information about their positions along the out-of-plane axis.

This problem can be partially overcome through the technique of metal-induced energy transfer (MIET), which introduces a thin metal film to the setup. The idea is that the apparatus picks up changes in the molecule’s fluorescence that are caused by the molecule coupling to collective excitations of surface plasmons in the film. Since this light emission varies with distance from the film, researchers can use MIET to calculate the molecule’s distance relative to the film surface, allowing them to locate it along the third axis. Yet with current versions of the technique, the accuracy of this out-of-plane measurement is 3–5 times worse than that of lateral localization, in the plane of the film.

Lifeb.

Once tooth enamel breaks or wears away it’s over – it doesn’t grow back. That’s why dentists have to plug in the gaps with artificial fillings. But now, a team of scientists from China’s Zhejiang University and Jiujiang Research Institute says it has finally figured out how to regrow tooth enamel, a development that could totally upend dental care. The team developed a gel that has been found to help mouse teeth regrow enamel within 48 hours. The research has been published in the journal Science Advances.

What exactly is enamel and why can’t it regrow? It is a mineralized substance with a highly complicated structure that covers the surface of teeth. The structure is made up of enamel rods interwoven with inter-rods in a fish scale pattern which makes it the hardest tissue in the human body. It is initially formed biologically but once mature it becomes acellular, meaning it becomes devoid of the ability to self-repair. This is why cavities (tooth decay) are one of the most prevalent chronic diseases in humans.

Continue reading “Scientists Develop Gel That Can Regrow Tooth Enamel” »

Proposed “Spaceline” space elevator to the moon could be feasible, and could simplify efforts to mine raw materials from the lunar surface.