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(1 - 2 of 2)
- Title
- HYBRID METHODS FOR SIMULATION OF MUON IONIZATION COOLING CHANNELS
- Creator
- Kunz, Josiah D.
- Date
- 2017, 2017-05
- Description
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COSY Infinity is an arbitrary-order beam dynamics simulation and analysis code. It can determine high-order transfer maps of combinations of...
Show moreCOSY Infinity is an arbitrary-order beam dynamics simulation and analysis code. It can determine high-order transfer maps of combinations of particle optical elements of arbitrary field configurations. For precision modeling, design, and optimization of next-generation muon beam facilities, its features make it a very attractive code. New features are being developed for inclusion in COSY to follow the distribution of charged particles through matter. To study in detail some of the properties of muons passing through material, the transfer map approach alone is not sufficient. The interplay of beam optics and atomic processes must be studied by a hybrid transfer map–Monte Carlo approach in which transfer map methods describe the average behavior of the particles in the accelerator channel including energy loss, and Monte Carlo methods are used to provide small corrections to the predictions of the transfer map accounting for the stochastic nature of scattering and straggling of particles. The advantage of the new approach is that it is very efficient in that the vast majority of the dynamics is represented by fast application of the high-order transfer map of an entire element and accumulated stochastic effects as well as possible particle decay. The gains in speed shown in this work are expected to simplify the optimization of muon cooling channels which are usually very computationally demanding due to the need to repeatedly run large numbers of particles through large numbers of configurations. This work describes the development of the required algorithms and their application to the simulation of muon ionization cooling channels. The code is benchmarked against other codes, validated with experimental results, and predicts results for current muon ionization cooling efforts.
Ph.D. in Physics, May 2017
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- Title
- Beam Line Design for Fully Staged Two Beam Acceleration at the Argonne Wakefield Accelerator Facility
- Creator
- Neveu, Nicole
- Date
- 2018
- Description
-
Two beam acceleration (TBA) is a candidate for future high energy physics machines and FEL user facilities. This is a scheme in which an...
Show moreTwo beam acceleration (TBA) is a candidate for future high energy physics machines and FEL user facilities. This is a scheme in which an electron accelerator uses a ``drive'' beam to transport and supply the RF power needed for acceleration on a secondary and independent 'witness' accelerator. This technology is attractive for its potential to improve the efficiency and simplicity of large scale machines. At the Argonne Wakefield Accelerator Facility (AWA), research into this potential accelerator scheme is ongoing. Completed experiments include a simplified staging set up, where high-charge, 65 MeV drive bunch trains were injected from the RF photoinjector into decelerating structures to generate a few hundred MW's of RF power. This RF power was transferred through an RF waveguide to accelerating structures that were used to accelerate the witness beam. Staging refers to the sequential acceleration (energy gain) in two or more structures on the witness beam line. The main limitation in past experiments was difficulty achieving 100\% transmission in the second stage which resulted in lower power generation. AWA plans to demonstrate fully staged TBA, which requires a separate beam line for each decelerating/accelerating pair. In this thesis, design specifications and initial hardware tests needed for a new, independent beam line for TBA was done. Simulations of the drive line were done using the code OPAL. Since OPAL was new to the AWA group, a benchmark comparison with ASTRA and GPT was done to validate initial results. Then two optimization algorithms were investigated and used to optimize the drive line at 40 nC. Comparison of results between the two algorithms were done, with no major discrepancies found. Then large scale and parallel optimizations were done for the optics configuration in the fully staged TBA beam line design. A kicker was designed and incorporated into the drive beam line to accomplish a modular design so that each accelerating structure can be independently powered by a separate drive beam. Experimental measurements of the kicker indicate the angle increases linearly with the supplied voltage, and the angle achieved meets the design requirements for fully staged TBA. Optics optimization was done to minimize the beam size at the center of the decelerating structures to ensure good charge transmission. The resulting design will be the basis for proof of principle experiments that will take place at the AWA facility.
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