Search
Menu
PI Physik Instrumente - Fast Steering LB LW 11/24

Topological Approach Boosts Efficiency of On-Chip Frequency Combs

Facebook X LinkedIn Email
Using a topological platform — topology is a field of abstract math that underlies some of the most peculiar behaviors of modern materials — researchers at the University of Maryland (UMD) have proposed a method to make chip-sized frequency combs 10x more efficient.

Postdoctoral researcher and lead author Sunil Mittal, Joint Quantum Institute Fellow Mohammad Hafezi, and their collaborators previously pioneered a micro-ring array with built-in topological protection and used it to supply single photons on demand and generate made-to-order entangled photons.

The latest work aimed to determine whether a similar setup — a square lattice of micro-ring resonators with extra “link” rings — could also be adapted to improve frequency comb technology.

In this setting, the micro-rings along the outer edge of the lattice become distinct from the rings in the middle. Light sent into the lattice spends most of its time along this outer edge and, due to the nature of the topological constraints, does not scatter into the center. The researchers call this outer circle of micro-rings a super-ring.

The team hoped to find conditions that would form a frequency comb in the pulses circulating around the super-ring. However, each of the rings in the lattice can have its own pulse of light circling around. To get one big pulse of light going around the super-ring, the pulses within each micro-ring would have to work together, syncing up to form an overall pulse going around the entire boundary.

Rendering of a light-guiding lattice of micro-rings that researchers predict will create a highly efficient frequency comb. Courtesy of Sunil Mittal, Joint Quantum Institute.

Rendering of a light-guiding lattice of micro-rings that researchers predict will create a highly efficient frequency comb. Courtesy of Sunil Mittal, Joint Quantum Institute.


Mittal and collaborators were unsure at what frequency or power this would happen, if at all. To test the system, Mittal wrote a program to simulate how light would traverse the 12-x-12 ring lattice.

AdTech Ceramics - Ceramic Packages 1-24 MR

The team successfully identified the parameters that made the micro-ring pulses sync up into a super-ring pulse, and also found that the efficiency was a factor of 10 higher than possible for a single ring comb.

The simulation showed that the comb’s teeth were spaced in accordance with the size of individual micro-rings, or wavelengths, that fold neatly around the small circle. However, zooming in on any of the individual teeth would show that they were really subdivided into smaller, more finely spaced sub-teeth, corresponding to the size of the super-ring.

Simply put, the incoming light was coupled with a few percent efficiency into each of these extra sub-teeth, allowing the aggregate efficiency to top 50%.

The team is working on an experimental demonstration of this topological frequency comb. Using simulations, they were able to single out silicon nitride as a promising material for the micro-rings, as well as figure out what frequency and power of light to send in.

Team members believe constructing their superefficient frequency comb should be within reach of current state-of-the art experimental techniques. Such a comb could support lidar in self-driving cars as well as compact optical clocks, the researchers said. Additionally, the presence of finely spaced sub-teeth around each individual tooth could, for example, also help add more information channels in a wavelength division multiplexing transmitter.

“There could be many applications which we don’t even know yet,” Mittal said. “We hope that there’ll be much more applications and more people will be interested in this approach.”

The research was published in Nature Physics (www.doi.org/10.1038/s41567-021-01302-3).

Published: September 2021
Glossary
quantum
The term quantum refers to the fundamental unit or discrete amount of a physical quantity involved in interactions at the atomic and subatomic scales. It originates from quantum theory, a branch of physics that emerged in the early 20th century to explain phenomena observed on very small scales, where classical physics fails to provide accurate explanations. In the context of quantum theory, several key concepts are associated with the term quantum: Quantum mechanics: This is the branch of...
frequency comb
A frequency comb is a precise and regular series of equally spaced spectral lines, or frequencies, that are generated with great accuracy. The term "frequency comb" is often associated with the Nobel Prize-winning technique known as frequency comb spectroscopy, developed by John L. Hall and Theodor W. Hänsch in the 1990s. The technology has since become a powerful tool in various scientific and technological applications. Key points about frequency combs: Origin and development: The...
lattice
In photonics, a lattice refers to a periodic arrangement of optical elements or structures, often on a microscopic or nanoscopic scale. These optical lattices can be created using various techniques such as lithography, etching, or deposition processes. The arrangement of these elements forms a regular grid-like pattern, analogous to the crystal lattice in solid-state physics. One common application of optical lattices is in photonic crystals, which are engineered materials with periodic...
lidar
Lidar, short for light detection and ranging, is a remote sensing technology that uses laser light to measure distances and generate precise, three-dimensional information about the shape and characteristics of objects and surfaces. Lidar systems typically consist of a laser scanner, a GPS receiver, and an inertial measurement unit (IMU), all integrated into a single system. Here is how lidar works: Laser emission: A laser emits laser pulses, often in the form of rapid and repetitive laser...
resonance
Resonance can be defined in various contexts, including physics, chemistry, and music. Here are definitions for resonance in a few different fields: Physics: In physics, resonance refers to the phenomenon where an oscillating system or object exhibits an increase in amplitude at its natural frequency when subjected to external forces or vibrations. This can occur when the frequency of an external force matches the natural frequency of the system, leading to a resonance effect. Chemistry: In...
micro-ring resonator
A micro-ring resonator is a compact optical device that utilizes the resonant behavior of light within a small ring-shaped waveguide structure to selectively enhance or filter certain wavelengths of light. Micro-ring resonators are essential components in integrated photonics and are used in various applications, including optical communication systems, sensing, and signal processing. Key features and principles of micro-ring resonators include: Ring structure: A micro-ring resonator...
quantumfrequency combMaterialslatticeJoint Quantum InstituteJoint Quantum Institute at the University of Marylandlidarresonancemicro-ring resonatormicro-ring resonatorslight emissionsafetyatomicOpticsoptical clocksdatacomtelecomCommunicationsAmericasResearch & TechnologyTech Pulse

We use cookies to improve user experience and analyze our website traffic as stated in our Privacy Policy. By using this website, you agree to the use of cookies unless you have disabled them.