Emrah Ilbey scite author profile

Emrah Ilbey

5Publications

59Citation Statements Received

51Citation Statements Given

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Bilkent University

Publications

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High-power high-repetition-rate single-mode Er-Yb-doped fiber laser system

Pavlov¹,

Ilbey²,

Dulgergil³

et al. 2012

Opt. Express

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We demonstrate an all-fiber-integrated, high-power chirped-pulse-amplification system operating at 1550 nm. The seed source is a soliton fiber laser with 156 MHz repetition rate. Two-stage single mode amplifier provides an amplification of more than 40 dB without significant spontaneous amplified emission. The power amplifier is based on cladding-pumped 10 µm-core Er-Yb co-doped fiber, the output of which was spliced into standard singlemode fiber. We obtain 10 W average power in a strictly singlemode operation. After dechirping with a grating compressor, near transform-limited, 450 fs-long pulses are obtained. The laser source exhibits excellent short and long-term intensity stability, with relative intensity noise measurements characterizing the short-term stability.

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Diffraction-limited, 10-W, 5-ns, 100-kHz, all-fiber laser at 155 μm

et al. 2014

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This Letter reports on an all-fiber-integrated master-oscillator, power amplifier system at 1.55 μm producing 5-ns, 100-μJ pulses. These pulses are generated at a 100 kHz repetition rate, corresponding to 10 W of average power. The seed source is a low-power, current-modulated, single-frequency, distributed feedback semiconductor laser. System output is obtained from a standard single-mode fiber (Corning SMF-28). Consequently, the beam is truly diffraction limited, which was independently proven by M2 measurements. Further increase of peak power is limited by onset of significant spectral broadening due to nonlinear effects, primarily four-wave mixing. Numerical simulations based on six-level rate equations with full position- and time-dependence were developed to model propagation of pulses through the amplifier chain. This capability allows minimization of the amplified spontaneous emission, which can be directly measured using a fast acousto-optic modulator to gate the pulses.

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10 W, 10 ns, 50 kHz all-fiber laser at 1.55 µm

Pavlov

Dulgergil

Ilbey

et al. 2012

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Nonlinear chirped-pulse amplification of a soliton-similariton laser to ~1 µJ at 1550 nm

Ilbey

Pavlov

Dulgergil

et al. 2012

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10-W, 156-MHz All-fiber-integrated Er-Yb-doped Fiber Laser-amplifier System

Pavlov

Ilbey

Dulgergil

et al. 2012

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Emrah Ilbey

High-power high-repetition-rate single-mode Er-Yb-doped fiber laser system

Diffraction-limited, 10-W, 5-ns, 100-kHz, all-fiber laser at 155 μm

10 W, 10 ns, 50 kHz all-fiber laser at 1.55 µm

Nonlinear chirped-pulse amplification of a soliton-similariton laser to ~1 µJ at 1550 nm

10-W, 156-MHz All-fiber-integrated Er-Yb-doped Fiber Laser-amplifier System

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