acm-header
Sign In

Communications of the ACM

ACM Careers

Researchers Create Novel Optical Fibers


View as: Print Mobile App Share:
Arash Mafi and Salman Karbasi of University of Wisconsin-Milwaukee

Professor Arash Mafi (left) pf the University of Wisconsin-Milwaukee and doctoral student Salman Karbasi (right) harnessed "Anderson localization" to create an optical fiber that propagates multiple beams of light in a single strand.

Credit: Peter Jakubowski / University of Wisconsin-Milwaukee

Researchers at the University of Wisconsin-Milwaukee (UWM) have found a new mechanism to transmit light through optical fibers. Their discovery marks the first practical application of a Nobel-Prize-winning phenomenon that was proposed in 1958.

Assistant Professor Arash Mafi and doctoral student Salman Karbasi harnessed "Anderson localization" to create an optical fiber with a strong scattering mechanism that traps the beam of light as it traverses the fiber. The work was done in collaboration with Karl Koch, a scientist with Corning Inc.

Data transmission through conventional optical fibers — in which only one spatial channel of light traverses the fiber — is the backbone of the Internet. Such single-core fibers, however, are reaching the limits of their information-carrying capacity, says Mafi.

Propagation of multiple optical beams in a single strand of optical fiber is a sought-after solution to overcome this limitation. The collaboration's novel discovery achieves this.

The work has potential in next-generation high-speed communication and biomedical imaging, but it also opens the door for more uses of "Anderson localization" in technology.

"Anderson localization" is named after physicist Philip W. Anderson, who first theoretically observed the curious containment of electrons in a highly disordered medium, an observation for which he shared the 1977 Nobel Prize in physics, but one that is still under investigation.

Mafi and Karbasi's fiber design consists of two randomly distributed materials, which scatter the photons.

The fiber's disordered interior causes a beam of light traveling through it to freeze laterally. The output light can follow any shift in the location of the entry point as it moves around on the cross-section of the fiber.

Karbasi says his theoretical calculations indicated that the proper fiber design would take advantage of Anderson localization. "We designed our fiber so that it provides more physical places where the light can propagate," says Karbasi.

Their research, backed by a grant from the National Science Foundation, was published as "Multiple-beam Propagation in an Anderson Localized Optical Fiber" in the journal Optics Letters.

The collaborators are currently working on forming and transmitting images using their unique method.

Before joining UWM's College of Engineering & Applied Science in 2008, Mafi was a senior research scientist at Corning Inc., the world's largest manufacturer of optical fibers. He earned an NSF Early CAREER award earlier this year.

Karbasi is first author on the publications. He has been studying with Mafi at UWM since 2009, after receiving his bachelor's and master's degrees in Iran.

 


 

No entries found

Sign In for Full Access
» Forgot Password? » Create an ACM Web Account