Abstract
Recording electric field evolution in single-shot with THz bandwidth is needed in science including spectroscopy, plasmas, biology, chemistry, Free-Electron Lasers, accelerators, and material inspection. However, the potential application range depends on the possibility to achieve sub-picosecond resolution over a long time window, which is a largely open problem for single-shot techniques. To solve this problem, we present a new conceptual approach for the so-called spectral decoding technique, where a chirped laser pulse interacts with a THz signal in a Pockels crystal, and is analyzed using a grating optical spectrum analyzer. By borrowing mathematical concepts from photonic time stretch theory and radio-frequency communication, we deduce a novel dual-output electro-optic sampling system, for which the input THz signal can be numerically retrieved—with unprecedented resolution—using the so-called phase diversity technique. We show numerically and experimentally that this approach enables the recording of THz waveforms in single-shot over much longer durations and/or higher bandwidth than previous spectral decoding techniques. We present and test the proposed DEOS (Diversity Electro-Optic Sampling) design for recording 1.5 THz bandwidth THz pulses, over 20 ps duration, in single-shot. Then we demonstrate the potential of DEOS in accelerator physics by recording, in two successive shots, the shape of 200 fs RMS relativistic electron bunches at European X-FEL, over 10 ps recording windows. The designs presented here can be used directly for accelerator diagnostics, characterization of THz sources, and single-shot Time-Domain Spectroscopy.
Highlights
IntroductionRecording the complete electric field of light in singleshot (including its envelope and carrier) is considered one of the “holy grails” of terahertz science
Recording the complete electric field of light in singleshot is considered one of the “holy grails” of terahertz science
We indicate the most commonly used crystal orientation, which corresponds to maximal Pockels effect. (*): For classic spectrally decoded EO sampling, several quarter wave plates (QWP) and half wave plates (HWP) configurations are possible and we indicate here the angles for the so-called balanced detection
Summary
Recording the complete electric field of light in singleshot (including its envelope and carrier) is considered one of the “holy grails” of terahertz science This type of detection is largely needed for investigating and mastering novel terahertz sources, as ultrashort pulse quantum cascade lasers[1], ultra-wide bandwidth laser-plasma-based terahertz sources[2], and terahertz Free-Electron-Lasers[3]. It was shown that this idea works only if the needed temporal resolution is larger than[8]: τR 1⁄4 pffiτffiffiwffiffiffiffiffiffiffiτffiffiLffi ð1Þ where τw is the duration of the chirped pulse on the crystal, and τL is the Fourier-transform limit duration (i.e., the pulse duration that may be reached when fully compressed)
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