Close

Search

Search Menu
Photonics Media Photonics Marketplace Photonics Spectra BioPhotonics Vision Spectra Photonics Showcase Photonics ProdSpec Photonics Handbook
LightMachinery Inc. - Picometer resolution

Topological Cavity Widens Functionality of Surface-Emitting Lasers

Facebook Twitter LinkedIn Email
Researchers at the Institute of Physics of the Chinese Academy of Sciences have incorporated a topological cavity into the design of a surface-emitting laser to create a device that addresses the challenge of simultaneously increasing output power and beam quality in semiconductor lasers — a principal bottleneck. The research team’s topological-cavity surface-emitting laser (TCSEL) achieved 10 W of peak power, subdegree beam divergence, a 60-dB side-mode suppression ratio, and 2D multiwavelength array lasing at 1550 nm — which is considered crucial for communication and is also an eye-safe wavelength.

The TCSEL was also demonstrated to operate at any other wavelength range. The laser’s specifications and capabilities give it promise for applications, including lidar and virtual reality, as well as in communications.

The laser’s design features a cavity that the same research team previously developed, called a Dirac-vortex topological cavity. The cavity offers high single-mode selection over a large area. It was proposed to overcome the bottlenecks of semiconductor lasers and simultaneously improve output power and beam quality.

Semiconductor lasers are widely used across applications due to their compact size, high efficiency, low cost, and wide spectra.

The researchers advanced the previous work and applied the cavity to a surface-emitting laser. They evaluated its performance by comparing it to existing industrial products that use single-mode semiconductor lasers — the distributed feedback (DFB) edge-emitting laser used in internet communication and the vertical-cavity surface-emitting laser (VCSEL) that enables cellphone facial recognition. These two lasers both adopt the midgap mode in their optimized 1D resonator designs.

The TCSEL realizes the 2D version of the topological midgap mode, which the researchers said is more suited for the planar process used for the manufacture of semiconductor chips.

By changing the lattice constant, the corresponding laser wavelength varies linearly from 1512 nm to 1616 nm. Each laser in the TCSEL 2D array works stably in a single mode with a side mode suppression ratio greater than 50dB. According to the developing researchers, thr 2D multi-wavelength TCSEL arrays can potentially enhance the wavelength-division multiplexing technology for high-capacity signal transmission and multispectral sensing applications. Courtesy of the Institute of Physics of the Chinese Academy of Sciences.
By changing the lattice constant, the corresponding laser wavelength varies linearly from 1512 to 1616 nm. Each laser in the TCSEL 2D array works stably in a single mode with a side-mode suppression ratio greater than 50 dB. According to the researchers, the 2D multiwavelength TCSEL arrays can potentially enhance the wavelength-division multiplexing technology for high-capacity signal transmission and multispectral sensing applications. Courtesy of the Institute of Physics of the Chinese Academy of Sciences.
The far field of the TCSEL is a vector beam with radial polarizations. This narrow divergence, of less than 1° without collimating lenses, reduces the size, complexity, and cost of the laser system, which supports larger systems such as those used for 3D sensing. From microscopy images, the researchers clearly visualized the vortex structure from the Dirac-vortex cavity in the TCSEL.

Further, the laser’s wavelength flexibility gives the device the ability to achieve monolithic 2D multiwavelength arrays. In comparison, VCSELs generally lack wavelength tunability since the vertical cavity, which determines the lasing wavelength, is epitaxy-grown. Although DFB lasers can adjust wavelength, a DFB laser can only achieve a 1D multiwavelength array for edge emission. In contrast, the wavelength of TCSEL can be arbitrarily adjusted during the planar fabrication process.

Each laser in the 2D array also works stably in a single mode with a side-mode suppression ratio greater than 50 dB. The 2D multiwavelength TCSEL arrays can potentially enhance the wavelength-division multiplexing technology for high-capacity signal transmission and multispectral sensing applications. 

The work was supported by the CAS, the Beijing Natural Science Foundation, the Ministry of Science and Technology of China, and the Natural Science Foundation of China.

The research was published in Nature Photonics (www.doi.org/10.1038/s41566-022-00972-6).

Photonics Spectra
Jul 2022
GLOSSARY
laser cavity
A means of optical confinement intended to increase the gain length of radiation prior to emission from the device. The means of optical confinement used to increase gain path length vary depending upon the properties of the beam desired within the lasing medium. High light intensities occur within a laser cavity and dielectric mirrors coated for the lasing wavelength are used.The position and curvature of the optical cavity elements may be altered in order to optimize the laser performance as...
cavity
In a laser, the optical resonator formed by two coaxial mirrors, one totally and one partially reflective, positioned so that laser oscillations occur.
distributed feedback (dfb) laser
A laser system in which feedback is used to make certain modes in the resonator oscillate more strongly than others. In semiconductor lasers, a periodic corrugation in the active layer replaces the cleaved end mirrors, and the grating spacing is chosen to distribute the feedback in both directions, creating a condition that can approach single-mode oscillation.
lattice
A regular spatial display of points representing, for example, the sites of atoms in a crystal.
laserssemiconductor laser arrayssemiconductor laser cavitylaser cavityCavityResearch & TechnologyeducationInstitute of Physics of the Chinese Academy of SciencesChinese Academy of Sciencessurface emitting laserTCSELtopological cavity surface emitting laserVCSELcommunicationCommunicationsdistributed feedback (DFB) laserdistributed feedbacklaser arrayslatticelattice constant matchingTechnology News

back to top
Facebook Twitter Instagram LinkedIn YouTube RSS
©2022 Photonics Media, 100 West St., Pittsfield, MA, 01201 USA, [email protected]

Photonics Media, Laurin Publishing
x Subscribe to Photonics Spectra magazine - FREE!
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.