Emittance compensation schemes for a superconducting rf injector

H Vennekate,P Murcek,P Lu,R Xiang,J Teichert,A Arnold

doi:10.1103/physrevaccelbeams.21.093403

H Vennekate, P Murcek + Show 4 more

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https://doi.org/10.1103/physrevaccelbeams.21.093403

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Abstract

Contemporary particle injector technologies provide different advantages depending on the chosen design. In the case of copper rf injectors these is primarily the high accelerating field, enabling the generation of high charge bunches with very low emittance. However, the cost of that is a comparably low repetition rate. DC guns, on the other hand, can provide higher repetition rates and consequently increased beam currents at lower beam quality, i.e., increased emittance. The concept of a superconducting rf injector offers the opportunity to combine the advantages of both these concepts. However, it demands special concepts for emittance compensation, as the common approach with overlapping magnetic fields during the rf acceleration interferes with the limitations of superconductivity. The ELBE SRF Gun project is one of the most advanced in this field. Gun II, the second SRF injector at the Electron Linear accelerator with high Brilliance and low Emittance (ELBE), introduces new features for emittance compensation which were studied in detail over the last years. One of these methods is the integration of a superconducting solenoid into the cryostat. Another method uses rf focusing by retracting the photocathode's tip from the last cell of the resonator. This paper discusses both of these schemes by briefly outlining their setups, discussing results of numerical simulations of their impact, and presenting results of initial experimental beam measurements with Gun II.

Highlights

Many future accelerator concepts, such as energy recovery linacs (ERLs) and high power free electron lasers (FELs), demand injectors capable of delivering high bunch charge at increased repetition rates
The ELBE accelerator facility at Helmholtz-Zentrum Dresden-Rossendorf (HZDR) in Dresden, Germany, offers a unique test environment as a CW machine, driving two FELs and several other secondary sources, which is ideal for the development and implementation of such a new particle source [9]
Besides feeding the current accelerator, the superconducting radio frequency (SRF) Gun is expected to be the injector for the proposed Dresden Advanced Light Infrastructure and is embedded in the Helmholtz-Alliance’s Gun cluster, cooperating for example with the BERLinPro project at HZB in Berlin

Summary

INTRODUCTION

Many future accelerator concepts, such as energy recovery linacs (ERLs) and high power free electron lasers (FELs), demand injectors capable of delivering high bunch charge at increased repetition rates. The development of superconducting radio frequency (SRF) electron injectors is of great interest [1,2,3,4,5,6,7,8] Among these projects, the ELBE SRF Gun is one of the earliest and most advanced, running since the late 1990s. Compared to Gun I, the field distribution inside the first half cell of the resonator has changed from 60% to 80% of the peak field in the π-mode Besides this improved resonator, the cryostat itself was extended in order to house an additional superconducting (SC) solenoid for emittance compensation of the accelerated electron bunches, see Fig. 1, [10,11]. Besides the initial copper cathode, used during the commissioning phase, the SRF Gun II has been operated with bulk magnesium and Cs2Te coated photocathodes [12]

RF FOCUSING

SIMULATION STUDIES

EXPERIMENTAL RESULTS

CONCLUSION