F.W. Helbing scite author profile

International audienceTheoretical studies of filamentation of ultra-short near-IR laser pulses propagating in a noble gas predict near single-cycle pulses with the intensity being clamped to the field ionization threshold. Experimental results show that this method is carrier envelope offset phase preserving and provides a very simple source for generating few-cycle intense laser pulses. This suggests a very simple design for the generation of ultra-short, sub-femtosecond XUV optical pulses

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Carrier–envelope-offset dynamics and stabilization of femtosecond pulses

Helbing¹,

Steinmeyer²,

Gallmann

et al. 2002

Appl Phys B

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Carrier-envelope offset phase-locking with attosecond timing jitter

Helbing¹,

Steinmeyer

Keller³

2003

IEEE J. Select. Topics Quantum Electron.

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Inside a femtosecond laser oscillator, no coupling mechanism between the propagation speeds of the carrier and the pulse envelope exists. Therefore, the relative delay between carrier and envelope of a femtosecond oscillator will exhibit irregular fluctuations unless this jitter is actively suppressed. Both intensity and beam pointing fluctuations in the laser can introduce carrier-envelope phase changes. Based on our analysis, we are capable of reducing or avoiding certain mechanisms by proper design of the laser cavity. We use such an optimized cavity to stabilize the carrier envelope-phase to an external reference oscillator with a long-term residual jitter corresponding to only 10 attoseconds in a (100 kHz-0.01 Hz) bandwidth. This is the smallest long-term timing jitter of a femtosecond laser oscillator demonstrated to date. However, it is important to note that this stabilization was obtained with an -to-2 heterodyne technique using additional external spectral broadening in a microstructure fiber which introduces additional carrier-envelope phase noise. We present a direct heterodyne measurement of this additional carrier-envelope phase noise due to the continuum generation process.Index Terms-Mode-locked lasers, optical Kerr effect, phase jitter, phase synchronization, ultrafast optics.

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Carrier-envelope offset dynamics of mode-locked lasers

Helbing¹,

Steinmeyer²,

Keller³

et al. 2002

Opt. Lett.

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We investigate coupling mechanisms between the amplitude and the carrier-envelope offset phase in mode-locked lasers. We find that nonlinear beam steering in combination with the intracavity prism compressor is the predominant mechanism that causes amplitude-to-phase conversion in our laser. A second mechanism, induced by self-steepening, is also identified. These mechanisms are important for stabilizing the carrier-envelope offset phase and also explain the extremely low pulse-to-pulse energy fluctuations observed in some lasers with carrier-envelope lock. The coupling mechanisms described have important implications for applications of few-cycle optical pulses.

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F.W. Helbing

Generation of intense, carrier-envelope phase-locked few-cycle laser pulses through filamentation

Self-compression of ultra-short laser pulses down to one optical cycle by filamentation

Carrier–envelope-offset dynamics and stabilization of femtosecond pulses

Carrier-envelope offset phase-locking with attosecond timing jitter

Carrier-envelope offset dynamics of mode-locked lasers

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