Teenage climate activist responds to criticism, saying ‘when haters go after your looks and differences … you know you’re winning’
Scientists have identified the mechanism that lets geckos regrow severed limbs, and they may get it to work in humans.
Non-Euclidean Worlds Engine
Posted in media & arts
Here’s a demo of a rendering engine I’ve been working on that allows for non-euclidean geometry.
Source Code and Executable:
https://github.com/HackerPoet/NonEuclidean
Music:
“Automatic Loving” — Dee Yan-Key
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This would be good for hoverboards and aircrafts.
Physicists have discovered a novel quantum state of matter whose symmetry can be manipulated at will by an external magnetic field. The methods demonstrated in a series of experiments could be useful for exploring materials for next-generation nano- or quantum technologies.
Close.
This makes for a microcosm of people on the outside looking in who do not follow on a regular basis. A basic headline of living forever followed by comments of doubt or silliness and the heat death of the universe. Of the experts, I like Sinclair’s answer best.
What do hideous mall t-shirts, emo bands from the mid-aughts, and gorgeously-wrought realist novels about dissolving marriages have in common? Simply this assertion: Life Sucks. And it does suck, undoubtedly, even for the happiest and/or richest among us, not one of whom is immune from heartbreak, hemorrhoids, or getting mercilessly ridiculed online.
Still, at certain points in life’s parade of humiliation and physical decay almost all of us feel a longing—sometimes fleeting, sometimes sustained—for it to never actually end. The live-forever impulse is, we know, driving all manner of frantic, crackpot-ish behavior in the fringier corners of the tech-world; but will the nerds really pull through for us on this one? What are our actual chances, at this moment in time, of living forever? For this week’s Giz Asks, we spoke with a number of experts to find out.
Incorporating individual metal atoms into a surface in the right way allows their chemical behavior to be adapted. This makes new, better catalysts possible.
They make our cars more environmentally friendly and they are indispensable for the chemical industry: catalysts make certain chemical reactions possible—such as the conversion of CO into CO2 in car exhaust gases—that would otherwise happen very slowly or not at all. Surface physicists at the TU Wien have now achieved an important breakthrough; metal atoms can be placed on a metal oxide surface so that they show exactly the desired chemical behavior. Promising results with iridium atoms have just been published in the renowned journal Angewandte Chemie.
A new unified theory for heat transport accurately describes a wide range of materials – from crystals and polycrystalline solids to alloys and glasses – and allows them to be treated in the same way for the first time. The methodology, which is based on the Green-Kubo theory of linear response and concepts from lattice dynamics, naturally accounts for quantum mechanical effects and thus allows for the predictive modelling of heat transport in glasses at low temperature – a feat never achieved before, say the researchers who developed it. It will be important for better understanding and designing heat transporting devices in a host of applications, from heat management in high-power electronics, batteries and photovoltaics to thermoelectric energy harvesting and solid-state cooling. It might even help describe heat flow in planetary systems.
“Heat transport is the fundamental mechanism though which thermal equilibrium is reached,” explains Stefano Baroni of the Scuola Internazionale Superiore di Studi Avanzati (SISSA) in Trieste, Italy, who led this research effort. “It can also be thought of as the most fundamental manifestation of irreversibility in nature – as heat flows from warm areas in the same system to cooler ones as time flows from the past to the future (the ‘arrow of time’). What is more, many modern technologies rely on our ability to control heat transport.”
However, despite its importance, heat transport is still poorly understood and it is difficult to simulate the heat transport of materials because of this lack of understanding. To overcome this knowledge gap, researchers employ various simulation techniques based on diverse physical assumptions and approximations for different classes of material – crystals on one hand and disordered solids and liquids on the other.