Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μm

Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μm

Monolithic waveguide laser devices are required to achieve on-chip lasing. In this work, a new design of a monolithic device with embedded Ag nanoparticles (NPs) plus the Nd:YAG ridge waveguide has been proposed and implemented. By using Ag+ ion implantation, the embedded Ag NPs are synthesized on t...

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Main Authors: Li Rang, Pang Chi, Li Ziqi, Dong Ningning, Wang Jun, Ren Feng, Akhmadaliev Shavkat, Zhou Shengqiang, Chen Feng
Format: Article
Language:English
Published: De Gruyter 2019-03-01
Series:Nanophotonics
Subjects:
metallic nanoparticles
surface plasmon resonance
Q-switched mode-locked laser
integrated photonics devices
nonlinear optics
Online Access:http://www.degruyter.com/view/j/nanoph.2019.8.issue-5/nanoph-2019-0035/nanoph-2019-0035.xml?format=INT
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spelling doaj-7c6dc888b8bd4d3bb99b3274f7733af22021-05-02T08:32:02ZengDe GruyterNanophotonics2192-86142019-03-018585986810.1515/nanoph-2019-0035nanoph-2019-0035Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μmLi Rang0Pang Chi1Li Ziqi2Dong Ningning3Wang Jun4Ren Feng5Akhmadaliev Shavkat6Zhou Shengqiang7Chen Feng8School of Physics, State Key Laboratory of Crystal Materials, Shandong University, 27 Shan Da Nan Lu, Jinan 250100, ChinaSchool of Physics, State Key Laboratory of Crystal Materials, Shandong University, 27 Shan Da Nan Lu, Jinan 250100, ChinaSchool of Physics, State Key Laboratory of Crystal Materials, Shandong University, 27 Shan Da Nan Lu, Jinan 250100, ChinaKey Laboratory of Micro-Nano Optoelectronic Materials and Devices, Key Laboratory of Materials for High-Power Laser, Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai 201800, ChinaKey Laboratory of Micro-Nano Optoelectronic Materials and Devices, Key Laboratory of Materials for High-Power Laser, Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai 201800, ChinaDepartment of Physics, Center for Ion Beam Application and Center for Electron Microscopy, Wuhan University, Wuhan 430072, ChinaHelmholtz-Zentrum Dresden-Rossendorf, Institute of Ion Beam Physics and Materials Research, Bautzner Landstr. 400, Dresden 01328, GermanyHelmholtz-Zentrum Dresden-Rossendorf, Institute of Ion Beam Physics and Materials Research, Bautzner Landstr. 400, Dresden 01328, GermanySchool of Physics, State Key Laboratory of Crystal Materials, Shandong University, 27 Shan Da Nan Lu, Jinan 250100, ChinaMonolithic waveguide laser devices are required to achieve on-chip lasing. In this work, a new design of a monolithic device with embedded Ag nanoparticles (NPs) plus the Nd:YAG ridge waveguide has been proposed and implemented. By using Ag+ ion implantation, the embedded Ag NPs are synthesized on the near-surface region of the Nd:YAG crystal, resulting in the significant enhancement of the optical nonlinearity of Nd:YAG and offering saturable absorption properties of the crystal at a wide wavelength band. The subsequent processing of the O5+ ion implantation and diamond saw dicing of crystal finally leads to the fabrication of monolithic waveguide with embedded Ag NPs. Under an optical pump, the Q-switched mode-locked waveguide lasers operating at 1 μm is realized with the pulse duration of 29.5 ps and fundamental repetition rate of 10.53 GHz, owing to the modulation of Ag NPs through evanescent field interaction with waveguide modes. This work introduces a new approach in the application of monolithic ultrafast laser devices by using embedded metallic NPs.http://www.degruyter.com/view/j/nanoph.2019.8.issue-5/nanoph-2019-0035/nanoph-2019-0035.xml?format=INTmetallic nanoparticlessurface plasmon resonanceQ-switched mode-locked laserintegrated photonics devicesnonlinear optics
collection DOAJ
language English
format Article
sources DOAJ
author Li Rang
Pang Chi
Li Ziqi
Dong Ningning
Wang Jun
Ren Feng
Akhmadaliev Shavkat
Zhou Shengqiang
Chen Feng
spellingShingle Li Rang
Pang Chi
Li Ziqi
Dong Ningning
Wang Jun
Ren Feng
Akhmadaliev Shavkat
Zhou Shengqiang
Chen Feng
Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μm
Nanophotonics
metallic nanoparticles
surface plasmon resonance
Q-switched mode-locked laser
integrated photonics devices
nonlinear optics
author_facet Li Rang
Pang Chi
Li Ziqi
Dong Ningning
Wang Jun
Ren Feng
Akhmadaliev Shavkat
Zhou Shengqiang
Chen Feng
author_sort Li Rang
title Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μm
title_short Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μm
title_full Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μm
title_fullStr Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μm
title_full_unstemmed Monolithic waveguide laser mode-locked by embedded Ag nanoparticles operating at 1 μm
title_sort monolithic waveguide laser mode-locked by embedded ag nanoparticles operating at 1 μm
publisher De Gruyter
series Nanophotonics
issn 2192-8614
publishDate 2019-03-01
description Monolithic waveguide laser devices are required to achieve on-chip lasing. In this work, a new design of a monolithic device with embedded Ag nanoparticles (NPs) plus the Nd:YAG ridge waveguide has been proposed and implemented. By using Ag+ ion implantation, the embedded Ag NPs are synthesized on the near-surface region of the Nd:YAG crystal, resulting in the significant enhancement of the optical nonlinearity of Nd:YAG and offering saturable absorption properties of the crystal at a wide wavelength band. The subsequent processing of the O5+ ion implantation and diamond saw dicing of crystal finally leads to the fabrication of monolithic waveguide with embedded Ag NPs. Under an optical pump, the Q-switched mode-locked waveguide lasers operating at 1 μm is realized with the pulse duration of 29.5 ps and fundamental repetition rate of 10.53 GHz, owing to the modulation of Ag NPs through evanescent field interaction with waveguide modes. This work introduces a new approach in the application of monolithic ultrafast laser devices by using embedded metallic NPs.
topic metallic nanoparticles
surface plasmon resonance
Q-switched mode-locked laser
integrated photonics devices
nonlinear optics
url http://www.degruyter.com/view/j/nanoph.2019.8.issue-5/nanoph-2019-0035/nanoph-2019-0035.xml?format=INT
work_keys_str_mv AT lirang monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
AT pangchi monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
AT liziqi monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
AT dongningning monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
AT wangjun monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
AT renfeng monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
AT akhmadalievshavkat monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
AT zhoushengqiang monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
AT chenfeng monolithicwaveguidelasermodelockedbyembeddedagnanoparticlesoperatingat1mm
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