Here's a truly awesome bowling trick, performed by Chris Barnes. The trick even has a name: 'The Flying Eagle' trick. He performs this cool bowling shot during a trick shot challenge. Enjoy!

It seems that in this case the mouse's courage pays off. The mouse trap proves to be just too old to handle the challenge...and BTW the ending is hilarious! Way to go Mr. Mouse

Why is the Buggati Veyron so special? Well here, in this video, you'll find out for yourself! It simply looks like the McLaren SLR is standing still! Maybe the Caparo T1 can challenge this beast. Enjoy!

Even though the traffic in this Moscow road intersection doesn't compare to the one I saw in India (here), it still makes one heck of a challenge turning left. Enjoy.

The use of an organic material has been put in place a structure capable of transmitting data at rates eight times higher than those of traditional devices . The study of materials capable of transmitting data at ever higher speeds is the constant challenge of the technology of optical communications. The use of a new organic material, tested by a team of U.S. and European research coordinated by Ivan Biaggi of Lehigh University (United States), has enabled to achieve data transfers much higher than that obtained so far with traditional devices. The novelty lies in the combination of structures in silicon with organic material, identified by the initials Ddmebt . This is essentially a kind of "nonlinear" device, able to change its molecular structure to the passage of light, making it propagate at high speed. To minimize interference with the passage of data, researchers have vaporized the organic material and the deposit left on the rails of silicon and in the spaces between them. In this way, explain the authors, the molecules are deposited "like snowflakes", forming a highly homogeneous plastic. It is precisely in the interstices between the rails of silicon, filled with new material, that the light passes at high speed, allowing you to transmit data up to 170 Gigabit per second (with the traditional structures, which consist only of silicon, you can reach a maximum speed around 20-30 Gigabit per second). Combining silicon with an architecture was needed to channel and confine the flow of light within very small spaces (the guide of silicon is separated by a few tens of nanometers).

The transfer of data will be hundred of times faster than that by radio waves. The promise is made by the first tests conducted by a German institute. Receiving images in Google Earth or photos of the Hubble telescope in real time may soon be reality. A German institute has experienced a communication system based on lasers which will transfer data at a rate one hundred times higher than that possible with radio waves. The technology was developed by researchers from the Fraunhofer Institute for Laser Technology in Aachen on the company's Tesat GmbH & Co. under a project funded by the German Aerospace Center (Dlr).