182 research outputs found
Analytical treatment of the wakefields driven by transversely shaped beams in a planar slow-wave structure
The suppression of transverse wakefield effects using transversely elliptical
drive beams in a planar structure is studied with a simple analytical model
that unveils the geometric nature of this phenomenon. By analyzing the
suggested model we derive scaling laws for the amplitude of the longitudinal
and transverse wake potentials as a function of the Gaussian beam ellipticity -
. We explicitly show that in a wakefield accelerator application it
is beneficial to use highly elliptical beams for mitigating transverse forces
while maintaining the accelerating field. We consider two scaling strategies:
1) aperture scaling, where we keep a constant charge to have the same
accelerating gradient as in a cylindrical structure and 2) charge scaling,
where aperture is the same as in the cylindrical structure and charge is
increased to match the gradient.Comment: 10 pages, 6 figure
Single-shot, transverse self-wakefield reconstruction from screen images
A single-shot method to reconstruct the transverse self-wakefields acting on
a beam, based only on screen images, is introduced. By employing numerical
optimization with certain approximations, a relatively high-dimensional
parameter space is efficiently explored to determine the multipole components
of the transverse-wakefield topology up to desired order. The reconstruction
technique complements simulations, which are able to directly describe the
wakefield composition based on experimental conditions. The technique is
applied to representative simulation results as a benchmark, and also to
experimental data on wakefield observations driven in dielectric-lined
structures.Comment: 10 pages, 8 figure
Approaching Petavolts per meter plasmonics using structured semiconductors
A new class of strongly excited plasmonic modes that open access to
unprecedented Petavolts per meter electromagnetic fields promise wide-ranging,
transformative impact. These modes are constituted by large amplitude
oscillations of the ultradense, delocalized free electron Fermi gas which is
inherent in conductive media. Here structured semiconductors with appropriate
concentration of n-type dopant are introduced to tune the properties of the
Fermi gas for matched excitation of an electrostatic, surface "crunch-in"
plasmon using readily available electron beams of ten micron overall dimensions
and hundreds of picoCoulomb charge launched inside a tube. Strong excitation
made possible by matching results in relativistic oscillations of the Fermi
electron gas and uncovers unique phenomena. Relativistically induced ballistic
electron transport comes about due to relativistic multifold increase in the
mean free path. Acquired ballistic transport also leads to unconventional heat
deposition beyond the Ohm's law. This explains the absence of observed damage
or solid-plasma formation in experiments on interaction of conductive samples
with electron bunches shorter than . Furthermore,
relativistic momentum leads to copious tunneling of electron gas allowing it to
traverse the surface and crunch inside the tube. Relativistic effects along
with large, localized variation of Fermi gas density underlying these modes
necessitate the kinetic approach coupled with particle-in-cell simulations.
Experimental verification of acceleration and focusing of electron beams
modeled here using tens of Gigavolts per meter fields excited in semiconductors
with free electron density will pave the way for Petavolts
per meter plasmonics.Comment: 16 pages, 10 figure
Simulation studies for dielectric wakefield programme at CLARA facility
Short, high charge electron bunches can drive high magnitude electric fields
in dielectric lined structures. The interaction of the electron bunch with this
field has several applications including high gradient dielectric wakefield
acceleration (DWA) and passive beam manipulation. The simulations presented
provide a prelude to the commencement of an experimental DWA programme at the
CLARA accelerator at Daresbury Laboratory. The key goals of this program are:
tunable generation of THz radiation, understanding of the impact of transverse
wakes, and design of a dechirper for the CLARA FEL. Computations of
longitudinal and transverse phase space evolution were made with Impact-T and
VSim to support both of these goals.Comment: 10 Pages, 4 Figures, Proceedings of EAAC2017 Conferenc
Tunable Electron Multibunch Production in Plasma Wakefield Accelerators
Synchronized, independently tunable and focused J-class laser pulses are
used to release multiple electron populations via photo-ionization inside an
electron-beam driven plasma wave. By varying the laser foci in the laboratory
frame and the position of the underdense photocathodes in the co-moving frame,
the delays between the produced bunches and their energies are adjusted. The
resulting multibunches have ultra-high quality and brightness, allowing for
hitherto impossible bunch configurations such as spatially overlapping bunch
populations with strictly separated energies, which opens up a new regime for
light sources such as free-electron-lasers
Machine learning-based analysis of experimental electron beams and gamma energy distributions
The photon flux resulting from high-energy electron beam interactions with
high field systems, such as in the upcoming FACET-II experiments at SLAC
National Accelerator Laboratory, may give deep insight into the electron beam's
underlying dynamics at the interaction point. Extraction of this information is
an intricate process, however. To demonstrate how to approach this challenge
with modern methods, this paper utilizes data from simulated plasma wakefield
acceleration-derived betatron radiation experiments and high-field
laser-electron-based radiation production to determine reliable methods of
reconstructing key beam and interaction properties. For these measurements,
recovering the emitted 200 keV to 10 GeV photon energy spectra from two
advanced spectrometers now being commissioned requires testing multiple methods
to finalize a pipeline from their responses to incident electron beam
information. In each case, we compare the performance of: neural networks,
which detect patterns between data sets through repeated training; maximum
likelihood estimation (MLE), a statistical technique used to determine unknown
parameters from the distribution of observed data; and a hybrid approach
combining the two. Further, in the case of photons with energies above 30 MeV,
we also examine the efficacy of QR decomposition, a matrix decomposition
method. The betatron radiation and the high-energy photon cases demonstrate the
effectiveness of a hybrid ML-MLE approach, while the high-field electrodynamics
interaction and the low-energy photon cases showcased the machine learning (ML)
model's efficiency in the presence of noise. As such, while there is utility in
all the methods, the ML-MLE hybrid approach proves to be the most
generalizable.Comment: 23 pages, 30 figure
Shear-Wave Elastography Assessments of Quadriceps Stiffness Changes prior to, during and after Prolonged Exercise: A Longitudinal Study during an Extreme Mountain Ultra-Marathon.
In sports medicine, there is increasing interest in quantifying the elastic properties of skeletal muscle, especially during extreme muscular stimulation, to improve our understanding of the impact of alterations in skeletal muscle stiffness on resulting pain or injuries, as well as the mechanisms underlying the relationships between these parameters. Our main objective was to determine whether real-time shear-wave elastography (SWE) can monitor changes in quadriceps muscle elasticity during an extreme mountain ultra-marathon, a powerful mechanical stress model. Our study involved 50 volunteers participating in an extreme mountain marathon (distance: 330 km, elevation: +24,000 m). Quantitative SWE velocity and shear modulus measurements were performed in most superficial quadriceps muscle heads at the following 4 time points: before the race, halfway through the race, upon finishing the race and after recovery (+48 h). Blood biomarker levels were also measured. A significant decrease in the quadriceps shear modulus was observed upon finishing the race (3.31±0.61 kPa) (p<0.001) compared to baseline (3.56±0.63 kPa), followed by a partial recovery +48 h after the race (3.45±0.6 kPa) (p = 0.002) across all muscle heads, as well as for each of the following three muscle heads: the rectus femoris (p = 0.003), the vastus medialis (p = 0.033) and the vastus lateralis (p = 0.001). Our study is the first to assess changes in muscle stiffness during prolonged extreme physical endurance exercises based on shear modulus measurements using non-invasive SWE. We concluded that decreases in stiffness, which may have resulted from quadriceps overuse in the setting of supra-physiological stress caused by the extreme distance and unique elevation of the race, may have been responsible for the development of inflammation and muscle swelling. SWE may hence represent a promising tool for monitoring physiologic or pathological variations in muscle stiffness and may be useful for diagnosing and monitoring muscle changes
Sextupole Correction of the Longitudinal Transport of Relativistic Beams in Dispersionless Translating Sections
Abstract We examine the use of sextupole magnets to correct nonlinearities in the longitudinal phase space transformation of a relativistic beam of charged particles in a dispersionless translating section, or dogleg. Through heuristic analytical arguments and examples derived from recent experimental efforts, augmented by simulations using the particle tracking codes PARMELA and ELEGANT, sextupole corrections are found to be effective in optimizing the use of such structures for beam compression or for shaping the current profile of the beam, by manipulation of the second-order longitudinal dispersion. Recent experimental evidence of the use of sextupoles to manipulate second-order horizontal and longitudinal dispersion of the beam is presented. The theoretical and experimental results indicate that these manipulations can be used to create an electron bunch with a current profile having a long ramp followed by a sharp cut-off, which is optimal for driving large amplitude wake fields in a plasma wake field accelerator
Hot spots and dark current in advanced plasma wakefield accelerators
Dark current can spoil witness bunch beam quality and acceleration efficiency in particle beam-driven plasma wakefield accelerators. In advanced schemes, hot spots generated by the drive beam or the wakefield can release electrons from higher ionization threshold levels in the plasma media. These electrons may be trapped inside the plasma wake and will then accumulate dark current, which is generally detrimental for a clear and unspoiled plasma acceleration process. Strategies for generating clean and robust, dark current free plasma wake cavities are devised and analyzed, and crucial aspects for experimental realization of such optimized scenarios are discussed
Positron Driven High-Field Terahertz Waves in Dielectric Material
Advanced acceleration methods based on wakefields generated by high energy
electron bunches passing through dielectric-based structures have demonstrated
GV/m fields, paving the first steps on a path to applications such as future
compact linear colliders. For a collider scenario, it is desirable that, in
contrast to plasmas, wakefields in dielectrics do not behave differently for
positron and electron bunches. In this Letter, we present measurements of large
amplitude fields excited by positron bunches with collider-relevant parameters
(energy 20 GeV, and particles per bunch) in a 0.4 THz,
cylindrically symmetric dielectric structure. Interferometric measurements of
emitted coherent Cerenkov radiation permit spectral characterization of the
positron-generated wakefields, which are compared to those excited by electron
bunches. Statistical equivalence tests are incorporated to show the charge-sign
invariance of the induced wakefield spectra. Transverse effects on positron
beams resulting from off-axis excitation are examined and found to be
consistent with the known linear response of the DWA system. The results are
supported by numerical simulations and demonstrate high-gradient wakefield
excitation in dielectrics for positron beams.Comment: 6 pages, 6 figure
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