"This could be compared to switching from older, dial-up internet to modern broadband, with high speed and quality," says Professor Peter Andrekson, Head of the Photonics Laboratory at the Department of Microtechnology and Nanoscience at Chalmers.
Optical communication makes it possible to send information over very long distances. The technology is useful in a range of applications, such as space communication and in fiber optic cables for internet traffic.
With communication based on light, rather than radio waves, we could, for example, quickly send high-resolution images from Mars. The information, carried by laser beams, could be sent with high speed from a transmitter on the planet to a receiver on Earth or on the Moon. Optical communication also allows us to use the internet around the world – whether the signal is transferred in optical fiber cables under the seabed or transmitted wirelessly.
Because the light – carrying the information between two distant points – loses power along the way, a large number of optical amplifiers are needed. Without amplifiers, up to 99 percent of the signal in an optical fiber cable would disappear within 100 kilometers.
A constant battle against excess noise
A well-known problem in optical communication, however, is that these amplifiers add excess noise that significantly impairs the quality of the signal you want to send or receive. Now, the Chalmers researchers present an extremely promising solution to an obstacle that has existed for decades.
“We have developed the world's first optical amplifier that significantly enhances the range, sensitivity and performance of optical communication, that does not generate any excess noise – and is also compact enough to be of practical use,” says Ping Zhao, Postdoc at the Photonics Laboratory at Chalmers and one of the lead authors of the scientific paper, now published in Science Advances.
The light amplification in the project is based on a principle known as the Kerr effect, which so far is the only known approach that amplifies light without causing significant excess noise. The principle has been demonstrated before, but never in such a compact format– previous versions were too bulky to be useful.
The new amplifier fits in a small chip just a few millimeters in size, compared to previous amplifiers that have been several thousand times larger.
Tiny, quiet, and with high performance
Additionally, the new amplifiers offer a level of performance high enough that they can be placed more sparingly, making them a more cost-effective option. They also work in a continuous wave (CW) operation rather than a pulsed operation only.
“What we demonstrate here represents the first CW operation with an extremely low noise in a compact integrated chip. This provides a realistic opportunity for practical use in a variety of applications. Since it’s possible to integrate the amplifier into very small modules, you can get cheaper solutions with much better performance, making this very interesting for commercial players in the long run,” says research leader Peter Andrekson.
The new results also open doors to completely new applications in both technology and science, explains Peter Andrekson.
“This amplifier shows unprecedented performance. We consider this to be an important step towards practical use, not only in communication, but in areas including quantum computers, various sensor systems and in metrology when making atmospheric measurements from satellites for Earth monitoring.”
More about the research:
- The scientific article "Overcoming the quantum limit of optical amplification in monolithic waveguides" has been published in Science Advances. The study was conducted by Zhichao Ye, Ping Zhao, Krishna Twayana, Magnus Karlsson, Victor Torres-Company and Peter Andrekson. The researchers work at the Department of Microtechnology and Nanoscience at Chalmers University of Technology.
- The Chalmers researchers present the first compact CW-pumped monolithic parametric amplifier, and in addition demonstrated a noise performance well below the conventional quantum limit. The results were enabled by the lowest loss ever achieved in a dispersion-engineered integrated waveguide silicon-nitride material platform.
- The research project has been funded by the Swedish Research Council (Grant VR-2015-00535 and VR-2020-00453) The Knut and Alice Wallenberg Foundation and Horizon 2020 Marie Skłodowska-Curie Innovative Training Network Microcomb (GA 812818).
- Read more: Find the previous press release from Peter Andrekson’s research group: https://news.cision.com/chalmers/r/the-most-sensitive-optical-receivers-yet-for-space-communications,c3208049
For more information, please contact:
Postdoc, Photonics Laboratory at Chalmers, Department of Microtechnology and Nanoscience, Chalmers University of Technology, email@example.com
Professor, Head of the Photonics Laboratory, Department of Microtechnology and Nanoscience, Chalmers University of Technology, +46 31 772 16 06, firstname.lastname@example.org
Text: Lovisa Håkansson and Mia Halleröd Palmgren
Photo: Henrik Sandsjö | Illustration: Yen Strandqvist