TREDI simulations for high-brilliance photoinjectors and magnetic chicanes

The TREDI Monte Carlo program is briefly described, devoting some emphasis to the Lienard-Wiechert potentials approach followed to account for self-field effects and the covariant technique devised to achieve regularization of electromagnetic fields. Some guidelines to the choice of the correct parameters to be used in the simulation are also sketched. The predictions obtained for the reference work point of the space-charge compensated SPARC photoinjector and a benchmark chicane designed to study coherent synchrotron radiation effects in a magnetic compressor are compared to those of other well-established simulation codes

Covariant self-fields regularization in dense electron beams

A critical issue in the development of coherent X-ray sources as FEL and SR facilities is the generation of high peak brilliance electron beams. Detailed simulations of such “dense” systems require self-interaction effects to be carefully accounted for in diverse dynamical conditions ranging from low energies where quasi-static space charge effects dominate, to the highly relativistic regimes of the kind encountered, e.g., in magnetic compressors, where acceleration fields prevail and retarded effects cannot be neglected. In principia prima Monte Carlo codes the electron beam is usually modelled as a collection of mutually interacting objects, whose number is bounded because of practical computer limitations. As a consequence suitable techniques must be devised to achieve stability and suppress numerical artifacts. In this paper a covariant approach to self-fields regularization is described, in the context of TREDI simulation code, a fully 3D Monte Carlo Accounting for electron beam self-interaction by means of Lienard-Wiechert retarded potentials

Life Cycle Assessment of a Lithium-Ion Battery Pack Unit Made of Cylindrical Cells

Saving energy is a fundamental topic considering the growing energy requirements with respect to energy availability. Many studies have been devoted to this question, and life cycle assessment (LCA) is increasingly acquiring importance in several fields as an effective way to evaluate the energy demand and the emissions associated with products’ life cycles. In this work, an LCA analysis of an existent lithium-ion battery pack (BP) unit is presented with the aim to increase awareness about its consumption and offering alternative production solutions that are less energy intensive. Exploiting the literature data about cradle-to-grave and cradle-to-gate investigations, and after establishing reasonable approximations, the main BP sub-elements were considered for this study, such as the plastic cells support, the Li-ion cells brick, the PCBs for a battery management system (BMS), the liquid-based battery thermal management system (BTMS) and the BP container. For each of these components, the impacts of the extraction, processing, assembly, and transportation of raw materials are estimated and the partial and total values of the energy demand (ED) and global warming potential (GWP) are determined. The final interpretation of the results allows one to understand the important role played by LCA evaluations and presents other possible ways of reducing the energy consumption and (Formula presented.) emissions

Focusing properties of linear undulators

This paper investigates the focusing properties of linear magnetic undulators, i.e., devices characterized by weak defocusing properties in the horizontal (wiggling) plane and strongly focusing in the vertical plane. The problem of identifying the conditions that ensure the existence of the electron beam eigenstates in the undulator lattice for a given working point of electron beam energy E_{b} and resonant wavelength λ_{r} is studied. For any given undulator lattice, a bandlike structure is identified defining regions in the (E_{b},λ_{r}) plane where no periodic matching condition can be found, i.e., it is not possible to transport the electron beam so that optical functions are periodic at lattice boundaries. Some specific cases are discussed for the SPARC FEL undulator

FULL TEMPORAL RECONSTRUCTION USING AN ADVANCED LONGITUDINAL DIAGNOSTIC AT THE SPARC FEL

FULL TEMPORAL RECONSTRUCTION USING AN ADVANCED LONGITUDINAL DIAGNOSTIC AT THE SPARC FE

Phase space analysis of velocity bunched beams

Peak current represents a key demand for new generation electron beam photoinjectors. Many beam applications, such as free electron laser, inverse Compton scattering, terahertz radiation generation, have efficiencies strongly dependent on the bunch length and current. A method of beam longitudinal compression (called velocity bunching) has been proposed some years ago, based on beam longitudinal phase space rotation in a rf field potential. The control of such rotation can lead to a compression factor in excess of 10, depending on the initial longitudinal emittance. Code simulations have shown the possibility to fully compensate the transverse emittance growth during rf compression, and this regime has been experimentally proven recently at SPARC. The key point is the control of transverse beam plasma oscillations, in order to freeze the emittance at its lowest value at the end of compression. Longitudinal and transverse phase space distortions have been observed during the experiments, leading to asymmetric current profiles and higher final projected emittances. In this paper we discuss in detail the results obtained at SPARC in the regime of velocity bunching, analyzing such nonlinearities and identifying the causes. The beam degradation is discussed, both for slice and projected parameters. Analytical tools are derived to experimentally quantify the effect of such distortions on the projected emittanc