Gallium nitride defect reduction technique improves LEDs

This article was originally published on our sister publication, ElectroIQ.

LEDs are an increasingly popular technology for use in energy-efficient lighting. Researchers from North Carolina State University have now developed a new technique that reduces defects in the gallium nitride (GaN) films used to create LEDs, making them more efficient.

LED lighting relies on GaN thin films to create the diode structure that produces light. The new technique reduces the number of defects in those films by two to three orders of magnitude. "This improves the quality of the material that emits light," says Dr. Salah Bedair, a professor of electrical and computer engineering at NC State and co-author, with NC State materials science professor Nadia El-Masry, of a paper describing the research. "For a given input of electrical power, the output of light can be increased by a factor of two." This is particularly true for low electrical power input and for LEDs emitting in the ultraviolet range.

The researchers started with a GaN film that was 2µm thick and embedded half of that thickness with large voids -- empty spaces that were 1-2µm long and 0.25µm in diameter. The researchers found that defects in the film were drawn to the voids and became trapped, leaving the portions of the film above the voids with far fewer defects.

Defects are slight dislocations in the crystalline structure of the GaN films. These dislocations run through the material until they reach the surface. By placing voids in the film, the researchers effectively placed a "surface" in the middle of the material, preventing the defects from traveling through the rest of the film.

"Without voids, the GaN films have approximately 1010 defects per square centimeter," Bedair says. "With the voids, they have 107 defects. This technique would add an extra step to the manufacturing process for LEDs, but it would result in higher quality, more efficient LEDs."

The paper, "Embedded voids approach for low defect density in epitaxial GaN films," was published online Jan. 17 by Applied Physics Letters. The paper was co-authored by Bedair; Pavel Frajtag, a Ph.D. student at NC State; Dr. Nadia El-Masry, a professor of material science and engineering at NC State; and Dr. N. Nepal, a former post-doctoral researcher at NC State now working at the Naval Research Laboratory. The research was funded by the U.S. Army Research Office.

NC State’s electrical and computer engineering and material science and engineering departments are part of the university’s College of Engineering.