Abstract
We present design and realization of an ultrabroadband optical spectrometer capable of measuring the spectral intensity of multioctave-spanning light sources on a single-pulse basis with a dynamic range of up to eight orders of magnitude. The instrument is optimized for the characterization of the temporal structure of femtosecond long electron bunches by analyzing the emitted coherent transition radiation spectra. The spectrometer operates within the spectral range of 250 nm to $11.35\text{ }\text{ }\ensuremath{\mu}\mathrm{m}$, corresponding to 5.5 optical octaves. This is achieved by dividing the signal beam into three spectral groups, each analyzed by a dedicated spectrometer and detector unit. The complete instrument was characterized with regard to wavelength, relative spectral sensitivity, and absolute photometric sensitivity, always accounting for the light polarization and comparing different calibration methods. Finally, the capability of the spectrometer is demonstrated with a coherent transition radiation measurement of a laser wakefield accelerated electron bunch, enabling to determine temporal pulse structures at unprecedented resolution.
Highlights
Precise knowledge of the temporal structure of ultrashort electron bunches is key to understanding and control of modern linear accelerator driven light sources (LSs) [1] and high-peak current applications like beam-driven plasma wakefield accelerators [2,3,4,5]
In order to benchmark the spectrometer under realistic experimental conditions, it was employed in a series of laser wakefield accelerator (LWFA) experiments
Summarizing, we presented the design, setup, full characterization, and first test of a spectrometer, which is suitable for measuring multioctave transition radiation (TR) spectra of ultrashort electron beams in a single shot
Summary
Precise knowledge of the temporal structure of ultrashort electron bunches is key to understanding and control of modern linear accelerator driven light sources (LSs) [1] and high-peak current applications like beam-driven plasma wakefield accelerators [2,3,4,5]. The future refinement of laser wakefield accelerator (LWFA) [8] and related LS concepts [9,10,11] relies on improved diagnostic capabilities of the longitudinal phase space. It represents the main motivation of the current work as the temporal profile of wakefield accelerated bunches of a few femtosecond duration [12,13,14,15] with potential substructures [16,17,18] is closely linked to acceleration and injection conditions.
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