Applications such as laser surgery might soon use black velvet to absorb radiation. Energy Science Laboratories, Inc. (ESLI, San Diego, CA) has developed a lightweight, carbon-based velvet-lined curtain that can be affixed to a surrounding metal hull, known as a beam dump, to catch and absorb stray light and radiation emitted by a highpower laser.
The concept of a velvet curtain emerged from a 2004 Missile Defense Agency (MDA) Small Business Innovation Research (SBIR) Phase II contract for ESLI to design a lightweight beam dump for MDA's Airborne Laser program. Testing was conducted at Lawrence Livermore National Laboratory, the Naval Research Laboratory, and various Army sites during the contract period that concluded late last year. The company is now continuing its quest to achieve an advanced technology readiness level by making the curtains available to the Defense Advanced Research Projects Agency (DARPA).
ESLI's involvement in velvet-based technologies spans more than two decades, and the company holds four carbon- velvet-architecture patents. While the MDA-funded curtains are specifically designed to suppress unwanted emissions from high-yield airborne lasers, the carbonbased fabric can be used in other applications. One example with widespread use is lining telescope walls with black velvet, which would act as a stray-light suppressor. ESLI anticipates carbon-velvet curtains might someday be converted to suppress expended energy from smaller, less powerful lasers, like
those used in laser surgery.
How it Works
Conventional velvet is a tufted fabric, usually made from silk, cotton, or synthetic fibers, where the tufted threads are cut in evenly distributed, short, dense piles. ESLI's velvet curtains have a unique carbon-based architecture. The material consists of short carbon fibers that stand vertically on a surface. Curtains are produced in sheets that are about 1/8" thick, each weighing only a few ounces per square yard. The sheets are customformed and fit for a laser's beam dump. Testing of ESLI's velvet curtains has taken place in specially designed tanks filled with a water solution used for containing high-power laser energy.
ESLI makes two varieties of velvet, each with carbon fibers attached to a substrate. One velvet uses a carbonfiber substrate (for high-power beams); the other uses a graphite substrate (for lower-intensity applications). A carbon-based adhesive is applied to attach the fibers to the substrates. Both velvets are processed at temperatures of 1,200°C or greater.
ESLI velvets provide a significant advantage over other stray-light and radiation-suppression materials: They will not degrade under the light intensity and temperatures of high-powered lasers. The company successfully tested its velvet curtains against laser beams emitting 100 watts per square centimeter and operating at temperatures around 2,000°C. This temperature equates to ten times the heat that other light-suppressing materials can withstand.
Carbon velvet's ability to withstand high-energy and high-temperature environments is also beneficial in minimizing heat contamination within the beam dump. For instance, in most beam dumps, there is a threat that any substance — such as a single strand of fiber — can degrade and become detached because of the heat reflected and absorbed when the laser is fired. Such incidents could cause a detached particle to be heated to such intensity that, if it were to hit a large beam dump's observation window or the laser itself, significant damage could occur. ESLI's velvets are designed to minimize such problems.
Where it Stands
Following successful tests during the SBIR contract, ESLI now looks to market its velvet curtains to laser manufacturers as well as systems integrators involved in laserintensive projects such as MDA's Airborne Laser program. Company officials remain hopeful that the readiness of the technology will result in new contracts and new business opportunities.
For more information on ESLI's carbon-based velvet curtain, click here . (Source: MDA TechUpdate, Missile Defense Agency, National Technology Transfer Center Washington Operations.)