Lasers stabilised

A compact method for stabilising lasers that uses a new design to reduce sensitivity to vibration and gravity has been demonstrated in the US.

A compact, inexpensive method for stabilising lasers that uses a new design to reduce sensitivity to vibration and gravity 100 times better than similar approaches has been demonstrated by scientists at

JILA

in Boulder, Colorado. JILA is a joint institute of the

US National Institute of Standards and Technology

(NIST) and the

University of Colorado at Boulder

.

The method, described in the July 15 issue of Optics Letters, stabilises laser light to a single frequency, so that it can be used as a reliable reference oscillator for technologies such as optical clocks and light-based radar (lidar). The new stabiliser design performs better than similar systems of comparable size and is much smaller and less expensive than the best-performing systems, according to physicist John Hall, a co-author of the paper.

Laser systems are highly sensitive to environmental disturbances, such as electronic "noise" and vibration from equipment with mechanical motors. To stabilise operations in cases when high precision is needed, lasers are often "locked" to a single wavelength/frequency using an optical "cavity," a small glass cylinder with a mirror facing inward on each end. Laser light bounces back and forth between the mirrors and, depending on the exact distance between them, only one wavelength will "fit" that distance best and be reinforced with each reflection.

Information from this stabilised laser light is then fed back to the laser source to keep the laser locked on this one frequency. But the cavity can vibrate, or expand in response to temperature changes, causing corresponding slight frequency changes. Researchers have tried various improvements such as using cavities made of low-expansion glass.

In the latest advance, the JILA team made the cavity shorter and positioned it vertically instead of horizontally, with symmetrical mounting supports so that gravity and vibration forces yield opposing distortions in the two halves, and balance out to zero net effect.

The system was demonstrated with an infrared laser. "We designed the cavity so it doesn't care if it's vibrating," says Hall, who helped develop a resonant cavity design two decades ago. "We get good performance with a complete reduction of complexity and cost."