Alexander Ody scite author profile

Ultralow emittance (≤ 20 nm, normalized) electron beams with 10 5 electrons per bunch are obtained by tightly focusing an ultrafast (∼ 100 fs) laser pulse on the cathode of a 1.6 cell radiofrequency photoinjector. Taking advantage of the small initial longitudinal emittance, a downstream velocity bunching cavity is used to compress the beam to < 10 fs rms bunch length. The measurement is performed using a thick high voltage deflecting cavity which is shown to be well-suited to measure ultrashort durations of bunching beams, provided that the beam reaches a ballistic longitudinal focus at the cavity center.

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Flat electron beam sources for DLA accelerators

Ody¹,

Musumeci²,

Maxson³

et al. 2017

Nuclear Instruments and Methods in Physics Research Section A:

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Single-pass high-efficiency terahertz free-electron laser

Fisher¹,

Park²,

Lenz³

et al. 2022

Nat. Photon.

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Challenges in simulating beam dynamics of dielectric laser acceleration

Niedermayer

Adelmann

Bettoni

et al. 2019

Int. J. Mod. Phys. A

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Dielectric Laser Acceleration (DLA) achieves the highest gradients among structure-based electron accelerators. The use of dielectrics increases the breakdown field limit, and thus the achievable gradient, by a factor of at least 10 in comparison to metals. Experimental demonstrations of DLA in 2013 led to the Accelerator on a Chip International Program (ACHIP), funded by the Gordon and Betty Moore Foundation. In ACHIP, our main goal is to build an accelerator on a silicon chip, which can accelerate electrons from below 100 keV to above 1 MeV with a gradient of at least 100 MeV/m. For stable acceleration on the chip, magnet-only focusing techniques are insufficient to compensate the strong acceleration defocusing. Thus, spatial harmonic and Alternating Phase Focusing (APF) laser-based focusing techniques have been developed. We have also developed the simplified symplectic tracking code DLAtrack6D, which makes use of the periodicity and applies only one kick per DLA cell, which is calculated by the Fourier coefficient of the synchronous spatial harmonic. Due to coupling, the Fourier coefficients of neighboring cells are not entirely independent and a field flatness optimization (similarly as in multi-cell cavities) needs to be performed. The simulation of the entire accelerator on a chip by a Particle In Cell (PIC) code is possible, but impractical for optimization purposes. Finally, we have also outlined the treatment of wake field effects in attosecond bunches in the grating within DLAtrack6D, where the wake function is computed by an external solver.

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Resonant phase matching by oblique illumination of a dielectric laser accelerator

Crisp¹,

Ody²,

Musumeci³

et al. 2021

Phys. Rev. Accel. Beams

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Alexander Ody

Direct Measurement of Sub-10 fs Relativistic Electron Beams with Ultralow Emittance

Flat electron beam sources for DLA accelerators

Single-pass high-efficiency terahertz free-electron laser

Challenges in simulating beam dynamics of dielectric laser acceleration

Resonant phase matching by oblique illumination of a dielectric laser accelerator

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