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10: Pulse Characterization

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    Characterization of ultrashort laser pulses with pulse widths greater than 20 ps can be directly performed electronically using high speed photo detec- tors and sampling scopes. Photo detectors with bandwidth of 100 GHz are available. For shorter pulses usually some type of autocorrelation or cross-correlation in the optical domain using nonlinear optical effects has to be performed, i.e. the pulse itself has to be used to measure its width, because there are no other controllable events available on such short time scales.

    • 10.1: Intensity Autocorrelation
      This page examines pulse duration measurements via second-harmonic intensity autocorrelation, outlining an experimental setup that reduces background noise. It covers the input pulse splitting, the use of a nonlinear optical crystal for second harmonic generation, and the representation of nonlinear polarization through electric field convolution. The page highlights when intensity autocorrelation is informative and discusses limitations concerning phase information.
    • 10.2: Interferometric Autocorrelation (IAC)
      This page covers the interferometric autocorrelation method for pulse characterization, emphasizing phase information, beam splitting, and SHG detection. It details the significance of maintaining identical beam paths and discusses the interplay of pulse shape and dispersion, including deducing phase distortions from IAC data. Additionally, it highlights techniques like FROG and SPIDER for ultra-short laser pulse analysis, underscoring their importance in understanding pulse properties.
    • 10.3: Frequency Resolved Optical Gating (FROG)
      This page covers Frequency Resolved Optical Gating (FROG), a method for characterizing ultrashort laser pulses through nonlinear optical interactions. It explains how FROG utilizes gating with a pulse to measure the electric field and obtain a time-frequency spectrogram, detailing inversion algorithms and the role of Fourier transforms.
    • 10.4: Spectral Interferometry and SPIDER
      This page covers the advancements in Spectral Phase Interferometry for Direct Electric-Field Reconstruction (SPI-DER) and its application for characterizing laser pulses. It contrasts SPI-DER with traditional methods, explaining its efficiency and precision through spectral shear and pulse reconstruction. The process involves generating replica pulses and performing spectral shearing using sum-frequency generation while addressing the effects of dispersion.

    This page titled 10: Pulse Characterization is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Franz X. Kaertner (MIT OpenCourseWare) via source content that was edited to the style and standards of the LibreTexts platform.