Gold. The word brings to mind wedding rings, buried treasure, and California in the 1840s.
But when gold is reduced to 1/100,000 the size of a human hair, it takes on an entirely new personality.
By attaching gold nanoparticles to the surface of a microlaser, researchers in the USC Viterbi School of Engineering demonstrated a frequency comb that takes up less space and requires 1000 times less power than current comb technology. But what exactly is a frequency comb?
A frequency comb is a device that can create a rainbow of light from a single color. These high-precision light sources have numerous applications in many fields like cybersecurity, detection of toxic chemicals, and GPS. However, industrial combs are generated using large systems requiring watts of input power. In order to create smaller systems that could enable residential or portable applications, the power requirements for wavelength generation and device size must be significantly reduced.
The research team led by Andrea Armani, a professor in the Mork Family Department of Chemical Engineering and Materials Science, has demonstrated frequency combs requiring only milliwatts of input power by attaching gold nanorods to the surface of a single microlaser. The interaction of the light from the microlaser with the gold particles results in many additional wavelengths being generated. This process is further improved by a polymer coating on the nanoparticles. The power reduction decreases the system’s footprint and takes the technology from the lab to real-world applications where both power consumption and size are important.
“These results exemplify what can happen if researchers from different fields work together on a basic science problem that has applied research impact,” says Armani, the Ray Irani Chair in Engineering and Materials Science, whose laboratory is part of the new USC Michelson Center for Convergent Bioscience opening this November.
“By combining expertise in optics and in nanomaterials, we made exceptionally fast progress that challenged and disproved the conventional thought in the field that gold nanoparticles would be detrimental to the laser.”
Co-lead author Vinh Diep describes the project as using innovations in nanomaterials to solve an integrated optics problem.
“The role of the gold nanorods is to increase the intensity of the light circulating in the device,” Diep says. “The higher-intensity light can then interact with organic molecules on the surface of the gold to generate other wavelengths of light. This combined effect allows for the comb generation to begin at a much lower power than the traditional pulsed-laser approach.”
Diep, a Materials Science PhD student, explains that a frequency comb that contains numerous emission wavelengths over a large wavelength range is advantageous. By using the gold nanorod coating, the research team observed a comb that can span over a wavelength range of 300 nanometers. Without the gold nanorods, a comb could not be generated at the same power.
Demonstrating a large range shows the device’s strong potential for applications in developing a portable chemical spectroscopy system, where the chemical signal only occurs at a specific wavelength, and the accuracy is dependent on the light source.
The research was led by Vinh Diep and Rigoberto Castro-Beltrán, a USC-Conacyt Scholar at the University of Guanajuato. Additional engineering researchers involved were fellow PhD student Soheil Soltani and post-doctoral scholar Eda Gungor. The study has been accepted for publication in ACS Photonics.
In recognition of its potential societal impact, the 2005 Nobel Prize in Physics was given for frequency comb generation.