Ultrafast fiber lasers for homeland security

Okhotnikov, Oleg G.

doi:10.1117/12.622168

Cited by 2 publications

(3 citation statements)

References 21 publications

(21 reference statements)

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“…Today, there is particular demand for high-power modelocked fibre lasers, where rare-earth-doped fibres offer a number of advantages over alternative gain media, including excellent beam quality, simple thermal management and a compact and robust design [1]. To achieve high powers, a master-oscillator-power-fibre-amplifier architecture is typically employed, comprising a mode-locked fibre oscillator followed by multiple amplifier stages [2].…”

Section: Introductionmentioning

confidence: 99%

Dispersion engineering of mode-locked fibre lasers

Woodward

2018

J. Opt.

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Mode-locked fibre lasers are important sources of ultrashort pulses, where stable pulse generation is achieved through a balance of periodic amplitude and phase evolutions. A range of distinct cavity pulse dynamics have been revealed, arising from interplay between dispersion and nonlinearity in addition to dissipative processes such as filtering. This has led to the discovery of numerous novel operating regimes, offering significantly improved laser performance. In this Topical Review, we summarise the main steady-state pulse dynamics reported to date through cavity dispersion engineering, including average solitons, dispersion-managed solitons, dissipative solitons, giant-chirped pulses and similaritons. Characteristic features and the stabilisation mechanism of each regime are described, supported by numerical modelling, in addition to the typical performance and limitations. Opportunities for further pulse energy scaling are discussed, in addition to considering other recent advances including automated self-tuning cavities and fluoride-fibre-based mid-infrared mode-locked lasers.

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Section: Introductionmentioning

confidence: 99%

Dispersion engineering of mode-locked fibre lasers

Woodward

2018

J. Opt.

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“…The pre-requisite of a short cavity length for high repetition rate operation can be achieved by using a waveguide cavity configuration. In a waveguide, the pump and laser modes are tightly confined within the waveguide core, facilitating a lower lasing threshold and improved slope efficiency [7], [30], [31]. It inherently guarantees good beam quality [31] and a stable cavity construction.…”

mentioning

confidence: 99%

“…In a waveguide, the pump and laser modes are tightly confined within the waveguide core, facilitating a lower lasing threshold and improved slope efficiency [7], [30], [31]. It inherently guarantees good beam quality [31] and a stable cavity construction. Also, waveguide cavities allow easy incorporation of SAs within the integrated cavity to facilitate efficient pulsed operation [7], [30].…”

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confidence: 99%

7.8-GHz Graphene-Based 2-μm Monolithic Waveguide Laser

Ren

Brown

Mary

et al. 2015

IEEE J. Select. Topics Quantum Electron.

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We report a pulsed waveguide laser working at 1944 nm, mode-locked with a saturable absorber consisting of a graphene film deposited on an output coupler mirror. The waveguide is created into a ceramic Thulium-doped Yttrium Aluminium Garnet by ultrafast laser inscription. Q-switched mode-locking is achieved, with 6.5 mW average output power and ∼7.8 GHz pulse rate. This is a convenient, compact, high repetition rate laser for various applications, such as medical diagnostics and spectroscopy.

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Ultrafast fiber lasers for homeland security

Cited by 2 publications

References 21 publications

Dispersion engineering of mode-locked fibre lasers

Dispersion engineering of mode-locked fibre lasers

7.8-GHz Graphene-Based 2-μm Monolithic Waveguide Laser

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