Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation

Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation

Light that can carry orbital angular momentum (OAM) has found a variety of applications in super-resolution microscopy, optical communications, and laser machining, bringing up the need for pure OAM light generation at on-demand power levels and wavelengths. Parametric four-wave mixing is a promisin...

Full description

Bibliographic Details
Main Authors: X. Liu, E. N. Christensen, K. Rottwitt, S. Ramachandran
Format: Article
Language:English
Published: AIP Publishing LLC 2020-01-01
Series:APL Photonics
Online Access:http://dx.doi.org/10.1063/1.5130715
id doaj-836820f836884de481e0f0c63ca1852e
record_format Article
spelling doaj-836820f836884de481e0f0c63ca1852e2020-11-24T22:41:26ZengAIP Publishing LLCAPL Photonics2378-09672020-01-0151010802010802-810.1063/1.5130715Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservationX. Liu0E. N. Christensen1K. Rottwitt2S. Ramachandran3Department of Electrical and Computer Engineering, Boston University, 8 Saint Mary’s St., Boston, Massachusetts 02215, USADepartment of Photonics Engineering, Technical University of Denmark, 2800 Kgs. Lyngby, DenmarkDepartment of Photonics Engineering, Technical University of Denmark, 2800 Kgs. Lyngby, DenmarkDepartment of Electrical and Computer Engineering, Boston University, 8 Saint Mary’s St., Boston, Massachusetts 02215, USALight that can carry orbital angular momentum (OAM) has found a variety of applications in super-resolution microscopy, optical communications, and laser machining, bringing up the need for pure OAM light generation at on-demand power levels and wavelengths. Parametric four-wave mixing is a promising platform for such source generation, and while investigations of higher-order fiber modes have revealed enhanced phase-matching possibilities, the role of the angular momentum of light in this process has not yet been substantially considered. Here, with a specially designed ring-core fiber in which over 16 OAM modes can be stably guided, we demonstrate the first experiments, to our knowledge, investigating nonlinear four wave mixing between OAM modes in an optical fiber. The large modal space as well as spin and OAM conservation rules enable a high diversity of phase matching conditions while also providing high selectivity. We report parametric wavelength translations of over 438 nm and the ability to obtain kilowatt peak-power level ∼ nanosecond pulses of pure OAM beams at user defined colors.http://dx.doi.org/10.1063/1.5130715
collection DOAJ
language English
format Article
sources DOAJ
author X. Liu
E. N. Christensen
K. Rottwitt
S. Ramachandran
spellingShingle X. Liu
E. N. Christensen
K. Rottwitt
S. Ramachandran
Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation
APL Photonics
author_facet X. Liu
E. N. Christensen
K. Rottwitt
S. Ramachandran
author_sort X. Liu
title Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation
title_short Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation
title_full Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation
title_fullStr Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation
title_full_unstemmed Nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation
title_sort nonlinear four-wave mixing with enhanced diversity and selectivity via spin and orbital angular momentum conservation
publisher AIP Publishing LLC
series APL Photonics
issn 2378-0967
publishDate 2020-01-01
description Light that can carry orbital angular momentum (OAM) has found a variety of applications in super-resolution microscopy, optical communications, and laser machining, bringing up the need for pure OAM light generation at on-demand power levels and wavelengths. Parametric four-wave mixing is a promising platform for such source generation, and while investigations of higher-order fiber modes have revealed enhanced phase-matching possibilities, the role of the angular momentum of light in this process has not yet been substantially considered. Here, with a specially designed ring-core fiber in which over 16 OAM modes can be stably guided, we demonstrate the first experiments, to our knowledge, investigating nonlinear four wave mixing between OAM modes in an optical fiber. The large modal space as well as spin and OAM conservation rules enable a high diversity of phase matching conditions while also providing high selectivity. We report parametric wavelength translations of over 438 nm and the ability to obtain kilowatt peak-power level ∼ nanosecond pulses of pure OAM beams at user defined colors.
url http://dx.doi.org/10.1063/1.5130715
work_keys_str_mv AT xliu nonlinearfourwavemixingwithenhanceddiversityandselectivityviaspinandorbitalangularmomentumconservation
AT enchristensen nonlinearfourwavemixingwithenhanceddiversityandselectivityviaspinandorbitalangularmomentumconservation
AT krottwitt nonlinearfourwavemixingwithenhanceddiversityandselectivityviaspinandorbitalangularmomentumconservation
AT sramachandran nonlinearfourwavemixingwithenhanceddiversityandselectivityviaspinandorbitalangularmomentumconservation
_version_ 1725702175830573056

Similar Items