Tapered diode-pumped continuous-wave alexandrite laser

Beyatli, Ersen; Baali, Ilyes; Sumpf, B.; Erbert, G.; Leitenstorfer, Alfred; Sennaroğlu, Alphan; Demırbas, Umıt

doi:10.1364/josab.30.003184

Cited by 48 publications

(30 citation statements)

References 65 publications

(105 reference statements)

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“…5, at crystal temperatures of 10 • C and 60 • C. The optimum wavelengths of 765 nm and 770 nm at 10 • C and 60 • C, respectively, are typical for Alexandrite [1,7,16]. Elevated temperatures extended the upper tuning range, as has been previously reported [2], but in turn increased the lower bound by 7 nm.…”

Section: Diode-pumped Wavelength Tunable Alexan-dritesupporting

confidence: 73%

Analytical model of tunable Alexandrite lasing under diode end-pumping with experimental comparison

Kerridge-Johns¹,

Damzen²

2016

J. Opt. Soc. Am. B

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An analytical model is formulated to support understanding and underpin experimental development of laser action in the promising diode end-pumped Alexandrite system. Closed form solutions are found for output power, threshold and slope efficiency that for the first time incorporate the combined effects of laser ground state absorption (GSA) and excited state absorption (laser ESA), along with pump excited state absorption (pump ESA), in the case of an end-pumping geometry. Comparison is made between model predictions and experimental results from a fibre-delivered diode end-pumped Alexandrite laser system, showing the impact of wavelength tuning, crystal temperature, laser output coupling, and intracavity loss. The model is broadly applicable to other quasi-three-level lasers with combined laser and pump ESA. A condition for bistable operation is also formulated.

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Section: Diode-pumped Wavelength Tunable Alexan-dritesupporting

confidence: 73%

Analytical model of tunable Alexandrite lasing under diode end-pumping with experimental comparison

Kerridge-Johns¹,

Damzen²

2016

J. Opt. Soc. Am. B

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“…The cavity loss L becomes a doubly important design parameter for systems with pump ESA, with regards to slope efficiency, as it reduces both η p and η c . The trend of slope efficiency with output coupling in Figure 5 has been seen in end-pumped Alexandrite lasers [14,15], which have pump ESA [16]. In these investigations it was suggested that this could be due to energy transfer upconversion -a process that had not been identified for Alexandrite in the literature.…”

Section: Discussionmentioning

confidence: 86%

“…The more exact formulations, (15) and (16), are also independent of σ 0 and N , assuming a suitably long gain medium and not excessive pumping (note I s is inversely proportional to σ 0 ).…”

Section: Discussionmentioning

confidence: 99%

Analysis of pump excited state absorption and its impact on laser efficiency

Kerridge-Johns

Damzen

2015

Laser Phys. Lett.

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Abstract. Excited state absorption (ESA) is a process that occurs in many laser gain media and can significantly impact their efficiencies of operation. In this work we develop a model to quantify the effect of ESA at the pump wavelength on laser efficiency, threshold and heating. In an analysis based on the common end pumped laser geometry we derive solutions and analytical expressions that model the laser behaviour. From these solutions we discuss the main parameters affecting efficiency, such as the laser cavity loss, pump ESA cross section and stimulated emission cross section. Methodologies are described to minimise the impact of pump ESA, for example by minimising cavity loss. It is also shown that altering the pumping geometry can significantly improve performance by improved distribution of the population inversion. Double end pumping can approximately halve the effect of pump ESA compared to single end pumping, and side pumping also has the potential to arbitrarily reduce its effect.

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“…Unlike Ti:sapphire, Alexandrite can be directly pumped with red laser diodes because its absorption band covers most of the visible spectral range [10,13]. In addition, its larger στ product [15] presents a prospect of lower laser threshold. Furthermore, a diode-pumped Alexandrite laser was shown to produce >26 W of output power in the continuous wave regime [13] which significantly exceeds output from widely used Ti:sapphire lasers.…”

Section: Introductionmentioning

confidence: 99%

InP/InGaP quantum-dot SESAM mode-locked Alexandrite laser

Rafailov

Krysa

Major

et al. 2018

Solid State Lasers XXVII: Technology and Devices

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A semiconductor saturable absorber mirror (SESAM) passively mode-locked Alexandrite laser was demonstrated. Using an InP/InGaP quantum-dot saturable absorber mirror, pulse duration of 420 fs at 774 nm was obtained. The laser was pumped at 532 nm and generated 325 mW of average output power in mode-locked regime with a pump power of 7.12 W. To the best of our knowledge, this is the first report of a passively mode-locked Alexandrite laser using SESAM in general and quantum-dot SESAM in particular.

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Tapered diode-pumped continuous-wave alexandrite laser

Cited by 48 publications

References 65 publications

Analytical model of tunable Alexandrite lasing under diode end-pumping with experimental comparison

Analytical model of tunable Alexandrite lasing under diode end-pumping with experimental comparison

Analysis of pump excited state absorption and its impact on laser efficiency

InP/InGaP quantum-dot SESAM mode-locked Alexandrite laser

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