AI Article Synopsis
- - Plasma wakefield acceleration is a groundbreaking technique that can rapidly boost particle beam energies to gigaelectronvolts in very short distances, making it potential for compact applications like free-electron lasers.
- - Despite the reduced size of the plasma accelerator, traditional magnetic optics are still used before and after the process, which require larger setups.
- - The research introduces a compact device featuring two active-plasma lenses, which enhances focusing and energy gain of particle beams, aiding in the miniaturization of accelerators for future, smaller-scale machinery.
Article Abstract
Plasma wakefield acceleration represented a breakthrough in the field of particle accelerators by pushing beams to gigaelectronvolt energies within centimeter distances. The large electric fields excited by a driver pulse in the plasma can efficiently accelerate a trailing witness bunch paving the way toward the realization of laboratory-scale applications like free-electron lasers. However, while the accelerator size is tremendously reduced, upstream and downstream of it the beams are still handled with conventional magnetic optics with sizable footprints and rather long focal lengths. Here we show the operation of a compact device that integrates two active-plasma lenses with short focal lengths to assist the plasma accelerator stage. We demonstrate the focusing and energy gain of a witness bunch whose phase space is completely characterized in terms of energy and emittance. These results represent an important step toward the accelerator miniaturization and the development of next-generation table-top machines.
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| http://dx.doi.org/10.1103/PhysRevE.109.055202 | DOI Listing |
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