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Thresholdless Nanoscale Coaxial Lasers

Technology Application

Nanolasers are integral for future photonic circuits, by enabling a range of optical applications from on-chip optical communication to imaging, spectroscopy, sensing, and lithography. In addition, by magnifying the quantum properties of the field, they also provide useful tools for in-depth investigations of atom-field interactions.

Detailed Technology Description

Researchers from UC San Diego have developed methods, devices and systems for producing compact solid state lasers with coaxial cavity geometries. This new laser technology operates in a continuous wave (CW) mode at room-temperature or at lower temperatures, and produces thresholdless lasing using a spectrally broadband gain medium. Specifically, this new resonator design leverages the unique properties of nanoscale coaxial structures for harnessing electrodynamical effects at sub-wavelengths and thus permits the size of the laser cavity to be scaled down without increasing the threshold power required to drive lasing.

Supplementary Information

Patent Number: US20140054475A1
Application Number: US13975205A
Inventor: Khajavikhan, Mercedeh | Fainman, Yeshaiahu
Priority Date: 23 Aug 2012
Priority Number: US20140054475A1
Application Date: 23 Aug 2013
Publication Date: 27 Feb 2014
IPC Current: H01S000530 | G01J000142
US Class: 250552 | 372075
Assignee Applicant: The Regents of the University of California
Title: NANOSCALE COAXIAL LASERS
Usefulness: NANOSCALE COAXIAL LASERS
Summary: Nanoscale coaxial laser used in e.g. optical communication device (claimed), optical sensor device (claimed).
Novelty: Nanoscale coaxial laser used in e.g. optical communication device, optical sensor device has coaxial cavity with low refractive index materials, each filled in predetermined location in hollow ring of metal housing

Industry

Optics

Sub Category

Laser

Application No.

8989232

Others

Related Materials

Khajavikhan M, et al. 2012. Thresholdless nanoscale coaxial lasers. Nature, 482, 204–207 (09 February 2012)
Electrical engineers build "no-waste" laser ScienceNews, 6-Mar-2012

Tech ID/UC Case

22683/2012-351-0

Related Cases

2012-351-0

*Abstract

Semiconductor lasers generate a large amount of undesired spontaneous emission before starting lasing oscillation, which degrades their efficiency and performance substantially. Therefore, lasers that emit almost no spontaneous emission have long been sought. Such 'thresholdless lasers', - where light output versus excitation power has no obvious threshold characteristic - lasing occurs at extremely low excitation powers. These lasers' superior performance is suited to optical applications.

Currently there are two main approaches to designing nanolasers. The first utilizes dielectric based structures. Dielectrics have low loss at optical frequencies. There are, however, drawbacks in using dielectric-based nanolasers: they are either large in size or their mode extends far out of the gain region, and thus they exhibit poor gain-mode overlap.

The other approach uses metal in a cavity. In recent years, nanoscale metallic, plasmonic, and metallo-dielectric cavities have shown to confine light in ultra-small volumes and to improve the gain-mode spatial overlap. However, existing metal-based nanolasers require high threshold pump power because of the significant absorption loss of the metals at optical frequencies.

*IP Issue Date

Mar 24, 2015

*Principal Investigator

Name: Mercedeh Khajavikhan

Department:

Name: Yeshaiahu Fainman

Department:

Country/Region

USA