Air Force Scientists Study Artificial Silk for Body Armor, Parachutes

Artificial silk fibers such as those shown here can be woven into sizeable, flexible fabrics using existing textile manufacturing methods. (Air Force photo by Donna Lindner)

Who doesn’t like to feel warm in the winter and cool in the summer?

Inspired by the qualities of fibers found in nature, scientists at the Air Force Research Laboratory and Indiana’s Purdue University are experimenting to develop a functional fiber that can be woven into sizeable, flexible fabrics using existing textile manufacturing methods.

Researchers are studying the cooling and temperature regulation properties of natural silk in order to apply it to synthetic fibers such as artificial spider silk, which is both stronger than the polymer known commercially as Kevlar and more flexible than nylon. Silk exhibits passive radiative cooling properties, meaning that it radiates more heat than it absorbs when in direct sunlight. On hot summer days, silk drops 10-15 degrees Fahrenheit when compared to reflective materials. The cooling fabric is of tremendous potential benefit to the warfighter wearing body armor.

Body armor and parachutes are two articles in line to be constructed with artificial spider silk. Body armor is burdensome due to its heavy weight and the non-breathing material they are fabricated with. Parachutes constructed of the new material are stronger and able to carry larger payloads. Estimates indicate that, while artificial spider silk may initially cost twice as much as Kevlar, the product’s minimal weight, incredible strength, elasticity and potential adaptability for other needs are characteristics that enhance its salability. Tents for forward operating bases could also be composed of the natural material. This would enable the warfighter to work in a cooler environment.

Fibroin, a silk protein secreted by the silkworm, can be processed into a lightweight material for fabricating artificially engineered synthetic and optical materials. The structured optical materials can reflect, absorb, concentrate or split light enabling a material to perform differently in a specific situation. Understanding light transport and heat transfer will lead to various innovations. According to AFRL researchers, learning from silk to assist with developing material synthesis and design processes in the future is a great opportunity.

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