The dispersion scan (d-scan) technique has emerged as a simple-to-implement characterization method for ultrashort laser pulses. D-scan traces are intuitive to interpret and retrieval algorithms that are both fast and robust have been developed to obtain the spectral phase and the temporal pulse profile. Here, we shortly review the second harmonic generation d-scan technique, focusing predominantly on results obtained at the Lund Laser Centre.We describe and compare recent implementations for the characterization of few- and multi-cycle pulses as well as two different approaches for recording d-scan traces in a single shot, thus showing the versatility of the technique
We present a new phase characterization technique for ultrashort laser pulses that employs self-phas...
In laser-matter interaction experiments, it is of paramount importance to characterize the laser pul...
We present an implementation of dispersion-scan based on self-diffraction (SD d-scan) and apply it t...
Ultrashort laser pulses play an important role in many applications in science and technology, from ...
Ultrashort laser pulses have become an indispensable tool in physics, chemistry and engineering. The...
We demonstrate a novel dispersion-scan (d-scan) scheme for single-shot temporal characterization of ...
We present a compact implementation of the ultrashort pulse measurement technique based on dispersio...
[EN] We demonstrate a single-shot ultrafast diagnostic, based on the dispersion-scan (d-scan) techni...
The precise characterization of femtosecond laser pulses is as challenging as their generation and a...
We investigate the performance of the recently introduced 'd-scan' technique for the characterizatio...
The dispersion scan (d-scan) technique is extended to measurement of the time-dependent polarization...
We propose and demonstrate a phase retrieval method using a novel variant of the dispersion scan (‘d...
The dispersion scan (d-scan) technique is extended to measurement of the timedependent polarization ...
Abstract In most applications of ultrashort pulse lasers, temporal compressors are used to achieve a...
High-field experiments are very sensitive to the exact value of the peak intensity of an optical pul...
We present a new phase characterization technique for ultrashort laser pulses that employs self-phas...
In laser-matter interaction experiments, it is of paramount importance to characterize the laser pul...
We present an implementation of dispersion-scan based on self-diffraction (SD d-scan) and apply it t...
Ultrashort laser pulses play an important role in many applications in science and technology, from ...
Ultrashort laser pulses have become an indispensable tool in physics, chemistry and engineering. The...
We demonstrate a novel dispersion-scan (d-scan) scheme for single-shot temporal characterization of ...
We present a compact implementation of the ultrashort pulse measurement technique based on dispersio...
[EN] We demonstrate a single-shot ultrafast diagnostic, based on the dispersion-scan (d-scan) techni...
The precise characterization of femtosecond laser pulses is as challenging as their generation and a...
We investigate the performance of the recently introduced 'd-scan' technique for the characterizatio...
The dispersion scan (d-scan) technique is extended to measurement of the time-dependent polarization...
We propose and demonstrate a phase retrieval method using a novel variant of the dispersion scan (‘d...
The dispersion scan (d-scan) technique is extended to measurement of the timedependent polarization ...
Abstract In most applications of ultrashort pulse lasers, temporal compressors are used to achieve a...
High-field experiments are very sensitive to the exact value of the peak intensity of an optical pul...
We present a new phase characterization technique for ultrashort laser pulses that employs self-phas...
In laser-matter interaction experiments, it is of paramount importance to characterize the laser pul...
We present an implementation of dispersion-scan based on self-diffraction (SD d-scan) and apply it t...