Ultrashort pulse generation in the mid-IR

Pires, Hugo; Baudisch, Matthias; Sánchez, D.; Hemmer, Michaël; Biegert, J.

doi:10.1016/j.pquantelec.2015.07.001

Cited by 100 publications

(52 citation statements)

References 228 publications

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“…3,4) Approaches to realize ∼2.7 µm lasing include semiconductor technology, stimulated transition of doped ions, and nonlinear wavelength conversion. [5][6][7][8][9] In terms of good beam quality and simple structure, the approach of stimulated transition of doped ions is highly desired. Among known ∼2.7 µm ion-doped lasers, Er-doped lasers operating on the 4 I 11=2 → 4 I 13=2 transition are widely studied since their highpower pump sources are commercially available.…”

Section: Introductionmentioning

confidence: 99%

Passive Q-switching of ∼2.7 µm Er:Lu₂O₃ceramic laser with a semiconductor saturable absorber mirror

Ren

Shen

Zhang

et al. 2018

Jpn. J. Appl. Phys.

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We demonstrate the passively Q-switched operation of an Er:Lu 2 O 3 ceramic laser at >2.7 µm for the first time, to the best of our knowledge. By using a semiconductor saturable absorber mirror (SESAM), stable pulse trains with a repetition rate of 20-33.3 kHz are produced in a compacted v-shaped resonator. The pulse duration (FWHM), pulse energy, and peak power are 660 ns, 1.8 µJ, and >2.73 W, respectively, at 33.3 kHz repetition rate. Prospects for further improvements in terms of laser performances are discussed.

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Section: Introductionmentioning

confidence: 99%

Passive Q-switching of ∼2.7 µm Er:Lu₂O₃ceramic laser with a semiconductor saturable absorber mirror

Ren

Shen

Zhang

et al. 2018

Jpn. J. Appl. Phys.

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“…Several important molecules offer resonances at the MIR wavelength, making them an optimum choice for spectroscopy [1]. Moreover, carrier-envelope phase (CEP)-stabilized few-cycle (sub-100 fs) laser pulses at long wavelengths are in high demand for complex experiments in attoscience and strong-field physics.…”

Section: Introductionmentioning

confidence: 99%

Kagome-fiber-based pulse compression of mid-infrared picosecond pulses from a Ho:YLF amplifier

Murari¹,

Stein²,

Çankaya³

et al. 2016

Optica

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Over the last decade, the development of ultrafast laser pulses in the mid-infrared (MIR) region has led to important breakthroughs in attosecond science and strong-field physics. However, as most such broadband MIR laser sources are near-IR pumped, the generation of high-intensity, long-wavelength MIR pulses is still a challenge, especially starting from picosecond pulses. Here we report, both experimentally and numerically, nonlinear pulse compression of sub-millijoule picosecond pulses down to sub-300 fs at 2050 nm wavelength in gas-filled Kagome-type hollow-core photonic crystal fibers for driving MIR optical parametric amplifiers. The pump laser is comprised of a compact fiber laser-seeded 2 μm chirped pulse amplification system based on a Ho:YLF crystal at 1 kHz repetition rate. Spectral broadening is studied for different experimental conditions with variations of gas pressure and incident pulse energies. The spectrally broadened 1.8 ps pulses with a Fourier-limited duration of 250 fs are compressed using an external prism-based compressor down to 285 fs and output energy of 125 μJ.

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“…When the DFG process generates a seed pulse in the terahertz (THz) domain, the process is called optical rectification, and it is widely benefiting from a new generation of non-oxide materials capable of providing optical transparency up to tens of µm, among which AgGaSe 2 (AGSe), ZnGeP 2 (ZGP), GaSe, GaP and ZnTe. A full list of NLO materials is provided in [24] for applications in the near-IR and in [25][26][27] for applications in the mid-IR.…”

Section: High-energy Few-optical Cycle Parametric Sources In the Ir Smentioning

confidence: 99%

Optical Parametric Amplification Techniques for the Generation of High-Energy Few-Optical-Cycles IR Pulses for Strong Field Applications

et al. 2017

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Abstract:Over the last few decades, the investigation of ultrafast phenomena occurring in atoms, molecules and solid-state systems under a strong-field regime of light-matter interaction has attracted great attention. The increasing request for a suitable optical technology is significantly boosting the development of powerful ultrafast laser sources. In this framework, Optical Parametric Amplification (OPA) is currently becoming a leading solution for applications in high-power ultra-broadband light burst generation. The main advantage provided by the OPA scheme consists of the possibility of exploring spectral ranges that are inaccessible by other laser technologies, as the InfraRed (IR) window. In this paper, we will give an overview on recent progress in the development of high-power few-optical-cycle parametric amplifiers in the near-IR and in the mid-IR spectral domain. In particular, the design of the most advanced OPA implementations is provided, containing a discussion on the key technical aspects. In addition, a review on their application to the study of strong-field ultrafast physical processes is reported.

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Ultrashort pulse generation in the mid-IR

Cited by 100 publications

References 228 publications

Passive Q-switching of ∼2.7 µm Er:Lu₂O₃ceramic laser with a semiconductor saturable absorber mirror

Passive Q-switching of ∼2.7 µm Er:Lu₂O₃ceramic laser with a semiconductor saturable absorber mirror

Kagome-fiber-based pulse compression of mid-infrared picosecond pulses from a Ho:YLF amplifier

Optical Parametric Amplification Techniques for the Generation of High-Energy Few-Optical-Cycles IR Pulses for Strong Field Applications

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Ultrashort pulse generation in the mid-IR

Cited by 100 publications

References 228 publications

Passive Q-switching of ∼2.7 µm Er:Lu2O3ceramic laser with a semiconductor saturable absorber mirror

Passive Q-switching of ∼2.7 µm Er:Lu2O3ceramic laser with a semiconductor saturable absorber mirror

Kagome-fiber-based pulse compression of mid-infrared picosecond pulses from a Ho:YLF amplifier

Optical Parametric Amplification Techniques for the Generation of High-Energy Few-Optical-Cycles IR Pulses for Strong Field Applications

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Product

Resources

About

Passive Q-switching of ∼2.7 µm Er:Lu₂O₃ceramic laser with a semiconductor saturable absorber mirror

Passive Q-switching of ∼2.7 µm Er:Lu₂O₃ceramic laser with a semiconductor saturable absorber mirror