Mechanisms of Spatiotemporal Mode-Locking

Thumbnail Image

Files

1911.09702.pdf (5.13 MB)

Links to Files

https://www.nature.com/articles/s41567-020-0784-1

Permanent Link

http://hdl.handle.net/11603/17105
 https://doi.org/10.1038/s41567-020-0784-1

Collections

UMBC Computer Science and Electrical Engineering Department
UMBC Faculty Collection

Author/Creator

Author/Creator ORCID

Date

2019-11-21

Type of Work

journal articles preprints
Text

Department

Program

Citation of Original Publication

Wright, Logan G.; Sidorenko, Pavel; Pourbeyram, Hamed; Ziegler, Zachary M.; Isichenko, Andrei; Malomed, Boris A.; Menyuk, Curtis R.; Christodoulides, Demetrios N.; Wise, Frank W.; Mechanisms of Spatiotemporal Mode-Locking; Optics (2019); https://arxiv.org/abs/1911.09702

Rights

This item is likely protected under Title 17 of the U.S. Copyright Law. Unless on a Creative Commons license, for uses protected by Copyright Law, contact the copyright holder or the author.

Subjects

mode-locking
optical resonator
nonlinear interactions
stable synchronization

Abstract

Mode-locking is a process in which different modes of an optical resonator establish, through nonlinear interactions, stable synchronization. This self-organization underlies light sources that enable many modern scientific applications, such as ultrafast and high-field optics and frequency combs. Despite this, mode-locking has almost exclusively referred to self-organization of light in a single dimension - time. Here we present a theoretical approach, attractor dissection, for understanding three-dimensional (3D) spatiotemporal mode-locking (STML). The key idea is to find, for each distinct type of 3D pulse, a specific, minimal reduced model, and thus to identify the important intracavity effects responsible for its formation and stability. An intuition for the results follows from the “minimum loss principle,” the idea that a laser strives to find the configuration of intracavity light that minimizes loss (maximizes gain extraction). Through this approach, we identify and explain several distinct forms of STML. These novel phases of coherent laser light have no analogues in 1D and are supported by experimental measurements of the three-dimensional field, revealing STML states comprising more than 10₇ cavity modes. Our results should facilitate the discovery and understanding of new higher-dimensional forms of coherent light which, in turn, may enable new applications.