New! Sign up for our free email newsletter.
Science News
from research organizations

Breaking the size and speed limit of modulators: The workhorses of the internet

Researchers develop fast, micrometer-size electro-optical modulator

Date:
April 13, 2020
Source:
George Washington University
Summary:
Researchers developed and demonstrated for the first time a silicon-based electro-optical modulator that is smaller, as fast as and more efficient than state-of-the-art technologies.
Share:
FULL STORY

Researchers developed and demonstrated for the first time a silicon-based electro-optical modulator that is smaller, as fast as and more efficient than state-of-the-art technologies. By adding indium tin oxide (ITO) -- a transparent conductive oxide found in touchscreen displays and solar cells -- to a silicon photonic chip platform, the researchers were able to create a compact device 1 micrometer in size and able to yield gigahertz-fast, or 1 billion times per second, signal modulation.

Electro-optical modulators are the workhorses of the internet. They convert electrical data from computers and smartphones to optical data streams for fiber optic networks, enabling modern data communications like video streaming. The new invention is timely since demand for data services is growing rapidly and moving towards next generation communication networks. Taking advantage of their compact footprint, electro-optic converters can be utilized as transducers in optical computing hardware such as optical artificial neural networks that mimic the human brain and a plethora of other applications for modern-day life.

THE SITUATION

Electro-optical modulators in use today are typically between 1 millimeter and 1 centimeter in size. Reducing their size allows increased packaging density, which is vital on a chip. While silicon often serves as the passive structure on which photonic integrated circuits are built, the light matter interaction of silicon materials induces a rather weak optical index change, requiring a larger device footprint. While resonators could be used to boost this weak electro-optical effect, they narrow devices' optical operating range and incur high energy consumption from required heating elements.

THE SOLUTION

By heterogeneously adding a thin material layer of indium tin oxide to the silicon photonic waveguide chip, researchers at the George Washington University, led by Volker Sorger, an associate professor of electrical and computer engineering, have demonstrated an optical index change 1,000 times larger than silicon. Unlike many designs based on resonators, this spectrally-broadband device is stable against temperature changes and allows a single fiber-optic cable to carry multiple wavelengths of light, increasing the amount of data that can move through a system.

FROM THE RESEARCHER

"We are delighted to have achieved this decade-long goal of demonstrating a GHz-fast ITO modulator. This sets a new horizon for next-generation photonic reconfigurable devices with enhanced performance yet reduced size," said Dr. Sorger


Story Source:

Materials provided by George Washington University. Note: Content may be edited for style and length.


Journal Reference:

  1. Rubab Amin, Rishi Maiti, Yaliang Gui, Can Suer, Mario Miscuglio, Elham Heidari, Ray T. Chen, Hamed Dalir, Volker J. Sorger. Sub-wavelength GHz-fast broadband ITO Mach–Zehnder modulator on silicon photonics. Optica, 2020; 7 (4): 333 DOI: 10.1364/OPTICA.389437

Cite This Page:

George Washington University. "Breaking the size and speed limit of modulators: The workhorses of the internet." ScienceDaily. ScienceDaily, 13 April 2020. <www.sciencedaily.com/releases/2020/04/200413165624.htm>.
George Washington University. (2020, April 13). Breaking the size and speed limit of modulators: The workhorses of the internet. ScienceDaily. Retrieved December 25, 2024 from www.sciencedaily.com/releases/2020/04/200413165624.htm
George Washington University. "Breaking the size and speed limit of modulators: The workhorses of the internet." ScienceDaily. www.sciencedaily.com/releases/2020/04/200413165624.htm (accessed December 25, 2024).

Explore More

from ScienceDaily

RELATED STORIES