Ultrasound Version of the Laser Built -- COMPAMED Trade Fair

Ultrasound Version of the Laser Built

"We have demonstrated that the essential nature of a laser can be mimicked by classical mechanics and not quantum mechanics in sound instead of light," said Richard Weaver, a professor of theoretical and applied mechanics at the University of Illinois at Urbana-Champaign.

To make a uaser (ultrasound amplification by stimulated emission of radiation), the researchers begin by mounting a number of piezoelectric auto-oscillators to a block of aluminum, which serves as an elastic, acoustic body. When an external acoustic source is applied to the body, the oscillators synchronize to its tone. Like fireflies trapped in a bottle, the oscillators synchronize to the frequency of the source.

In the absence of an external source, the tiny ultrasonic transducers become locked to one another by virtue of their mutual access to the same acoustic system.

"The phases must be correct also," Weaver said. "By carefully designing the transducers, we can assure the correct phases and produce stimulated emission. As a result, the power output scales with the square of the number of oscillators."

The uaser more closely resembles a "random laser" than it does a conventional, highly directional laser, Weaver said. "In principle, however, there is no reason why we shouldn't be able to design a uaser to generate a narrow, highly directional beam."

Optical lasers are useful because of their coherent emission, high intensity and rapid switching. These features are of little value in acoustics, where coherence is the rule and not the exception, intensity is limited by available power, and maximum switching speeds are limited by moderate frequencies.

The uaser produces ultrasonic waves that are coherent and of one frequency. With these longer wavelengths and more convenient frequencies, uasers could prove useful for modelling and studying laser dynamics. They could also serve as highly sensitive scientific tools for measuring the elastic properties and phase changes of modern materials, such as thin films or high-temperature superconductors.

COMPAMED.de; Source: University of Illinois at Urbana-Champaign