57 research outputs found
Tailored electron bunches with smooth current profiles for enhanced transformer ratios in beam-driven acceleration
Collinear high-gradient beam-driven wakefield methods for
charged-particle acceleration could be critical to the realization of compact,
cost-efficient, accelerators, e.g., in support of TeV-scale lepton colliders or
multiple-user free-electron laser facilities. To make these options viable, the
high accelerating fields need to be complemented with large transformer ratios
, a parameter characterizing the efficiency of the energy transfer between
a wakefield-exciting "drive" bunch to an accelerated "witness" bunch. While
several potential current distributions have been discussed, their practical
realization appears challenging due to their often discontinuous nature. In
this paper we propose several alternative current profiles which are smooth
which also lead to enhanced transformer ratios. We especially explore a
laser-shaping method capable of generating one the suggested distributions
directly out of a photoinjector and discuss a linac concept that could possible
drive a dielectric accelerator
Longitudinal phase space synthesis with tailored 3D-printable dielectric-lined waveguides
Longitudinal phase space manipulation is a critical and necessary component
for advanced acceleration concepts, radiation sources and improving
performances of X-ray free electron lasers. Here we present a simple and
versatile method to semi-arbitrarily shape the longitudinal phase space of a
charged bunch by using wakefields generated in tailored dielectric-lined
waveguides. We apply the concept in simulation and provide examples for
radiation generation and bunch compression. We finally discuss the
manufacturing capabilities of a modern 3D printer and investigate how printing
limitations, as well as the shape of the input LPS affect the performance of
the device
Self-calibration technique for characterization of integrated THz waveguides
Emerging high-frequency accelerator technology in the terahertz regime is
promising for the development of compact high-brightness accelerators and high
resolution-power beam diagnostics. One resounding challenge when scaling to
higher frequencies and to smaller structures is the proportional scaling of
tolerances which can hinder the overall performance of the structure.
Consequently, characterizing these structures is essential for nominal
operation. Here, we present a novel and simple self-calibration technique to
characterize the dispersion relation of integrated hollow THz-waveguides. The
developed model is verified in simulation by extracting dispersion
characteristics of a standard waveguide a priori known by theory. The extracted
phase velocity does not deviate from the true value by more than . In experiments the method demonstrates its ability to measure
dispersion characteristics of non-standard waveguides embedded with their
couplers with an accuracy below and precision of . Equipped with dielectric lining the metallic waveguides act as slow
wave structures, and the dispersion curves are compared without and with
dielectric. A phase synchronous mode, suitable for transverse deflection, is
found at .Comment: to be submitted to $\textit{Physical Review Accelerators and Beams}
Superradiant Cherenkov-Wakefield radiation as THz source for FEL facilities
An electron beam passing through a tube which is lined on the inside with a
dielectric layer will radiate energy in the THz range due to the interaction
with the boundary. The resonant enhancement of certain frequencies is
conditioned by structure parameters as tube radius and permittivity of the
dielectric layer. In low loss structures narrow-band radiation is generated
which can be coupled out by suitable antennas. For higher frequencies the
coupling to the resistive outer metal layer becomes increasingly important. The
losses in the outer layer prohibit to reach high frequencies with narrow-band
conditions. Instead short broad-band pulses can be generated with still
attractive power levels. In the first section of the paper a general theory of
the impedance of a two-layer structure is presented and the coupling to the
outer resistive layer is discussed. Approximate relations for the radiated
energy, power and pulse length for a set of structure parameters are derived
and compared to numerical results in the following section. Finally first
numerical result of the out-coupling of the radiation by means of a Vlasov
antenna and estimates of the achieved beam quality are presented.Comment: submitted for publicatio
Beam manipulation and acceleration with dielectric-lined waveguides
Advisors: Philippe Piot.Committee members: David Hedin; Stephen Martin; Vladimir Shiltsev.The development of next-generation TeV+ electron accelerators will require either immense footprints based on conventional acceleration techniques or the development of new higher--gradient acceleration methods. One possible alternative is beam-driven acceleration in a high-impedance medium such as a dielectric-lined-waveguide (DLW), where a high-charge bunch passes through a DLW and can excite gradients on the order of GV/m. An important characteristic of this acceleration class is the transformer ratio which characterizes the energy transfer of the scheme. This dissertation discusses alternative methods to improve the transformer ratio for beam-driven acceleration and also considers the use of DLWs for beam manipulation at low energy.Ph.D. (Doctor of Philosophy
Longitudinal Phase Space Synthesis with Tailored 3D-Printable Dielectric-Lined Waveguides
Longitudinal phase space manipulation is critical and necessary for advanced acceleration concepts, radiation sources and improving the performance of X-ray free electron lasers. Here we present a simple and versatile method to semi-arbitrarily shape the longitudinal phase space of a charged bunch by using wakefields generated in tailored dielectric-lined waveguides. We apply the concept in simulation and provide examples for radiation generation and bunch compression. We finally discuss the manufacturing capabilities of a modern 3D printer and investigate how printing limitations, as well as the shape of the input LPS affect the performance of the device
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