Yeah...here's the reason why they have this rule. A pretty good rule know that you think about it. But, what about medical metal parts(bolts, prosthesis, and so on)? What happens with them? Anyway, it's cool! Enjoy!

Metallica's popular song Enter Sandman played on a weird vibration instrument called a Kazoo. Somewhat weird, but kind of cool! Enjoy!

Fero-magnetic fluid is the stuff that Ferrari makes its car suspensions from. It's a fluid containing iron particles. When an electromagnetic force is applied to it, it tends to shape itself to the wave lines of the electromagnetic field. You can try something similar at home with some iron shavings on a plate, and a magnet underneath the plate. It's used in car suspensions because it can modify the stiffness of the ride almost instantly. Her's another use for fero-magnetic fluid, this time with beauty in mind, and less practical. Enjoy it!

If at first glance it seems an improbable association, Ice Age and Rammstein look, feel and most important sound well together (that's if you like rock). Here are two videos on this theme, which I hope you'll enjoy!

Some clips of Thermite from Brainiac science abuse. Thermite burns at around 4000 °F (2500 °C) and can cut just about anything. Watch it destroy anything in its path! Cool.

This guy tried to shoot a .50 caliber M107 sniper rifle in a piece of metal. What he didn't expect was that the piece of metal would ricochet back and hit him in the head! Luckily he had protection...ear protection

A cool demonstration of how liquid metal (actually an exotic alloy) can store energy and then return it, in a surprisingly elastic way. Enjoy the liquid metal demo video!

I've got to tell you, that I didn't believe in this myth. The energy from the mobile phone is so little that, you aren't able to get a spark. Things change if the energy is "stored" in the crumpled aluminum foil, and making lots of calls. The only realistic scenario I can come up with is that your car or some other piece of metal is already statically charged and your phone is the water drop that fills the glass. Anyway, it's very unlikely!

The new devices can operate at 30 degrees above zero, rather than less than 70. This is the characteristic of the new generation of semiconductors, researched at the Italian Institute for the Physics of Matter (INFM-CNR), and in the Ludwig Maximilian University in Monaco of Bavaria and the ETH Zurich (the study). Today there are two ways to record information on a medium: the electronic format, in which the binary language is the passage of electrons (the transistors) and magnetic (MRAM memory), more recently, in which the binary language is given by state of magnetization. To communicate these two systems could boost significantly the computational schemes, pending the distant quantum computer. Doubling the processing power and memory of a chip while maintaining the size, without the need to go in nano-scale (a scale, that is, a billionth of a meter) are just two of the technology that promises magnetic semiconductors suggest a near future. These devices were made over ten years ago, but so far required temperatures far below zero to work. The problem now seems outdated as the known semiconductors gallium arsenide containing traces of manganese, a metal which has ferromagnetic properties at around 200 degrees below zero. To increase the temperature threshold, above which the ferromagnetic behavior disappears, the researchers deposited on a semiconductor film of iron - metal known for its magnetic properties - the thickness of a few nanometers. Iron and manganese interacted so effectively that the new material, has a ferromagnetic behavior up to 30 degrees above zero, a jump of over a hundred degrees above the starting temperature. This result is a technological response parallel to that of the race to miniaturization and the research was selected the American Physical Society as one of the most important published in Physical Review Letters

The switch that turns off and on to command the superconducting property of the new device is a trivial electric field. In practice, what has been done by Andrea Ankle and colleagues at the University of Geneva in the first superconducting transistors. The operation, represents a milestone of applied physics and paves the way for the development of a new generation of microchips - and therefore computers - much faster than at present. To understand how and why the device is considered so promising it must be from another discovery, made last year by the same group of university research in Switzerland and published in Science. In one study, physicists have created a single crystal in which two metal oxides (strontium titanate and lanthanum aluminate) are separated. Between these two materials, researchers have found a layer of free electrons (electronic cloud) and 0.3 Kelvin - that is just above absolute zero - traveling without any resistance. At that temperature, the crystal becomes a superconductor. Scientists have now discovered how to turn off and turn on the superconductivity of this crystal at will, or modules, simply by applying an electric field to the point of contact between the two oxides. The result is a version of superconductive field effect transistors (FET) devices known in applied physics, able to switch from one state to a semiconductor insulator, and basic digital information in electronics (the fact that the current can pass or not is used as a binary 1-0 to store information). As the field effect transistors is a semiconductor, however, it always has resistance to the passage of current. This means that the speed at which you can get the electrons when the device is "on" is limited which means heat develops beyond a certain limit. This side effect is damaging the transistor. A superconducting transistor, however, can pass electrons (and record information) much more quickly, as it does not oppose any resistance to the passage of current and, therefore, not heat. There remains the problem of extremely low temperatures required for superconductivity. A limit that research is a long time trying to overcome.

A new technique, developed in the laboratories of the Foundation San Raffaele Biomedical Park, facilitates the process of regeneration of muscle tissue. Stem cells, modified at the level of genes, could permit the recovery of tissue degenerated from Duchenne muscular dystrophy (Dmd), even when the disease is in an advanced stage. This is a further step towards developing a therapy, which is being developed for some years by researchers of the Foundation San Raffaele Biomedical Park of Castel Romano, coordinated by Giulio Cossu, University of Milan. The research, published in Nature Medicine, was conducted by Cesare Gargioli and Marcello Coletta, along with Fabrizio de Grandis and Stefano Cannata at the Roman Tor Vergata. From previous studies and experiments on animal models it is known that mesangioblasti, stem cells normally associated with blood vessels, are able to spread easily and merge with and into the muscle tissue regenerating it (cell therapy). In advanced stages, however, this treatment had so far proven ineffective because of difficulties to penetrate between the muscle fibers. The degeneration, in fact, is accompanied by a process of inflammation followed by scarring tissue that impedes the provision of blood (and thus oxygen) to the muscles. Therefore, the muscle fibers are replaced with fatty tissue. To overcome the obstacle, the researchers genetically modified cells derived from the tendons (fibroblasts) so as to make them express the protein metalloproteasi 9 (Mmp9), a molecule that can degrade collagen that accumulates between fibres degeneration.

It was finally demonstrated how atoms arrange themselves inside the materials. This opens new possibilities for designing ultraresistant objects. Glass is a material called 'amorphous', whose atoms that is, are not disposed in a regular type structures crystal. The substance is not considered a solid but, rather, a liquid with very high viscosity. An international research team, led by Paddy Royall University of Bristol (Great Britain), in collaboration with Japanese and Australian scholars, is now able to demonstrate that during the solidification particles have in-shaped structures that prevent the icosahedron formation of crystals. Unlike solid crystalline form, in which the atoms are fixed to one another by chemical bonds into regular geometric structures, glass appears' solid 'just because the movement of each particle is physically prevented by the presence of other neighbouring atoms. The particles, that is, hinder each other. It was thus finally confirmed, with a simulation test, a 50 years old theory that explains many of the characteristics of this material and that could allow us to build, for example, non-crystalline metals much more resistant than traditional ones.

How can you convert waste into energy in the most efficient way possible? The secret is in riboflavin. The microorganisms have the ability to change the chemistry of the environment. This is known for a long time, but if some of these can generate energy from the degradation of organic compounds has not yet been clarified. One answer comes from an American study published in Proceedings of the National Academy of Sciences (Pnas): BioTechnology researchers from the Institute of the University of Minnesota have found that the riboflavin, better known as vitamin B-2, is the key to the production of electricity by the microorganism Shewanella, a bacterium that is commonly found in water and soil.