Low-dimensional materials as saturable absorbers for pulsed waveguide lasers

Li, Ziqi; Pang, Chi; Li, Rang; Chen, Feng

doi:10.1088/2515-7647/ab8a5a

Cited by 7 publications

(5 citation statements)

References 159 publications

(139 reference statements)

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“…Low-dimensional nanocarbons such as graphene and carbon nanotubes have been successfully recognized as suitable SAs in Q-switched [17][18][19][20][21] and mode-locked Yb 3+ -doped fs-DLW WG lasers. [22][23][24][25] They exhibit superior optical properties including ultra-broadband nonlinear absorption, large nonlinearity and ultrafast relaxation time, and enable a relatively low cost and facile fabrication process. [26,27] In addition, they possess a high level of robustness and chemical (environmental) stability compared with other nanomaterials.…”

Section: Introductionmentioning

confidence: 99%

Controllable Dynamic Single‐ and Dual‐Channel Graphene Q‐Switching in a Beam‐Splitter‐Type Channel Waveguide Laser

Bae

Calmano

Kränkel

et al. 2022

Laser & Photonics Reviews

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Direct inscription of structures by femtosecond-laser pulses facilitates the flexible fabrication of diverse optical channel waveguides in dielectric laser gain media. Among them, beam-splitter-type waveguide lasers have been recently studied; however, there is a lack of investigations on the effect of unique characteristics of such waveguides, such as controlled splitting ratios of output powers and selectable excitation of individual channels, for pulsed laser operation. Here, dynamic single-and dual-channel graphene Q-switching of an Yb:YAG waveguide consisting of one input and two output channels is demonstrated by controlling the power-splitting ratio. Single-channel Q-switched operation, exhibiting typical Q-switched pulses, is achieved by interaction between the graphene saturable absorber and the desired one of the two channels. When both channels exceed the Q-switching threshold, dual-channel Q-switching generates a pulse train that simultaneously combines the separately Q-switched pulses induced from each channel under excitation with a single pump source. At a fixed power-splitting ratio, the pulsed mode can be dynamically switched between the single-and dual-channel Q-switched operations by varying the pump power. The beam-splitter-type waveguide laser demonstrated in this study can be further developed for multiple-channel Q-switching, high-repetition-rate mode-locking, and on-chip dual-comb sources advantageous for diverse applications in optical communication, metrology, and sensing.

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Section: Introductionmentioning

confidence: 99%

Controllable Dynamic Single‐ and Dual‐Channel Graphene Q‐Switching in a Beam‐Splitter‐Type Channel Waveguide Laser

Bae

Calmano

Kränkel

et al. 2022

Laser & Photonics Reviews

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“…, which allows us to simulate the optical response at varying intensities of light. This model is applicable to many saturable absorbing materials, including quantum dots [18], rare-earth ions [19], and low dimensional materials [20]. The response of the saturable absorbers to an incident electric field is described by the Maxwell Bloch equations [21], which allow us to calculate 𝜒 !"…”

Section: Saturable Absorber Modelmentioning

confidence: 99%

Low power threshold, ultrathin optical limiter based on a nonlinear zone plate

2021

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Ultrathin optical limiters are needed to protect light sensitive components in miniaturized optical systems. However, it has proven challenging to achieve a sufficiently low optical limiting threshold. In this work, we theoretically show that an ultrathin optical limiter with low threshold intensity can be realized using a nonlinear zone plate. The zone plate is embedded with nonlinear saturable absorbing materials that allow the device to focus low intensity light, while high intensity light is transmitted as a plane wave without a focal spot. Based on this proposed mechanism, we use the finite-difference time-domain method to computationally design a zone plate embedded with InAs quantum dots as the saturable absorbing material. The device has a thickness of just 0.5 𝜇m and exhibits good optical limiting behavior with a threshold intensity as low as 0.45 kW/cm 2 , which is several orders of magnitude lower than current ultrathin flat-optics-based optical limiters. This design can be optimized for different operating wavelengths and threshold intensities by using different saturable absorbing materials. Additionally, the diameter and focal length of the nonlinear zone plate can be easily adjusted to fit different systems and applications. Due to its flexible design, low power threshold, and ultrathin thickness, this optical limiting concept may be promising for application in miniaturized optical systems.

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“…[ 35 ] Li et al reviewed recent advances in pulsed waveguide lasers based on low‐dimensional materials. [ 36 ] Kuznetsov et al reported preparing MoSe 2 , NiO, VO 2 , Bi 2 Se 3 , Bi 2 Te 3 , and Sb 2 Te 3 nanolayers using MOCVD technology. The transition from CW to Q‐switch mode is realized for several samples with taper diameters less than 11 µm.…”

Section: Introductionmentioning

confidence: 99%

TMO‐Derived γ‐MnO₂ Nanosheets for Harmonic Soliton Molecule Pulses Generation

Feng

Peng

et al. 2022

Annalen der Physik

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The interaction of 2D materials with ultrashort laser excitation generates fiber soliton pulses with extreme nonlinear absorption characteristics, which are essential for generating ultrafast pulses. However, searching for suitable nanomaterials to achieve versatile photonic properties is difficult. Factors such as cost, manufacturing process complexity, optical response time, and nonlinear absorption effects make the balance between high performance and low cost a constant challenge, greatly hindering the research and development of ultrafast photonics technology. For fiber soliton pulse systems, 𝜸-MnO 2 , as a transition metal oxide (TMO), shows excellent potential among many candidate nanomaterials due to its rich narrow-band optoelectronic microstructural features and nonlinear optical properties. In this work, this fundamental trade-off is overcome and 𝜸-MnO 2 is investigated as a nonlinear optical material for multifunctional fiber soliton pulsed lasers. The outputs of conventional soliton pulses, 23rd order harmonic soliton-molecule picosecond pulses, continuous and soliton pulse waves coexist in dual-wavelength, and soliton rain pulses are obtained simultaneously, successfully achieving a technological breakthrough in nanophotonics and pulse dynamics. It is demonstrated that MnO 2 has a broad application prospect for generating nonlinear effects such as fiber optic soliton pulses, which provides an effective and rich theoretical support for developing ultrafast photonics of narrow-band optoelectronic materials.

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Low-dimensional materials as saturable absorbers for pulsed waveguide lasers

Cited by 7 publications

References 159 publications

Controllable Dynamic Single‐ and Dual‐Channel Graphene Q‐Switching in a Beam‐Splitter‐Type Channel Waveguide Laser

Controllable Dynamic Single‐ and Dual‐Channel Graphene Q‐Switching in a Beam‐Splitter‐Type Channel Waveguide Laser

Low power threshold, ultrathin optical limiter based on a nonlinear zone plate

TMO‐Derived γ‐MnO₂ Nanosheets for Harmonic Soliton Molecule Pulses Generation

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Low-dimensional materials as saturable absorbers for pulsed waveguide lasers

Cited by 7 publications

References 159 publications

Controllable Dynamic Single‐ and Dual‐Channel Graphene Q‐Switching in a Beam‐Splitter‐Type Channel Waveguide Laser

Controllable Dynamic Single‐ and Dual‐Channel Graphene Q‐Switching in a Beam‐Splitter‐Type Channel Waveguide Laser

Low power threshold, ultrathin optical limiter based on a nonlinear zone plate

TMO‐Derived γ‐MnO2 Nanosheets for Harmonic Soliton Molecule Pulses Generation

Contact Info

Product

Resources

About

TMO‐Derived γ‐MnO₂ Nanosheets for Harmonic Soliton Molecule Pulses Generation