Hernandez-Garcia, C.; Krasilnikov, M.; Asova, G.; Bakr, M.; Boonpornprasert, P.; Godd, J.; Gross, M.; Huck, H.; Isaev, I.; Kalantaryan, D.; Khojoyan, M.; Kourkafas, G.; Lishlin, O.; Malyutin, D.; Melkumyna, D.; Oppelt, A.; Otevrel, M.; Pathak, G.; Renier, Y.; Rublack, T.; Stephan, F.; Vashchenko, G.; Zaho, Q.: Charge production studies from Cs2TE photocathodes in a normal conductiong RF gun. Nuclear Instruments & Methods in Physics Research A 871 (2017), p. 97-104
10.1016/j.nima.2017.06.051
Open Access Version (externer Anbieter)
Abstract:
This work discusses the behavior of electron bunch charge produced in an L-band normal conducting radio frequency gun from Cs2Te photocathodes illuminated with ps-long UV laser pulses and presumed homogeneous flattop laser transverse distribution. The measured charge shows the expected linear dependence in the quantum efficiency limited emission regime at low laser pulse energies. At higher laser pulse energy, the measured charge in the space charge limited emission regime should saturate, assuming an ideal homogeneous flattop laser transverse distribution. However, this behavior is not observed experimentally. Instead of saturating, the measured charge continues to increase with laser pulse energy, albeit with much weaker dependence than in the quantum efficiency limited emission regime. Simulations with the space charge particle tracking code ASTRA show that the charge saturates as expected using a homogeneous flattop laser transverse distribution. The discrepancy between simulations and measured excess charge may be attributed to the presence of unintentional Gaussian-like decaying radial halo beyond the core of the otherwise presumed homogeneous flattop core. The rate of increase of the measured charge at high laser pulse energies seems to be proportional to the amount of halo despite charge saturation in the core of the transverse laser radial profile. By utilizing core + halo particle distributions based on measured radial laser profiles, ASTRA simulations and semi-analytical emission models reproduce the behavior of the measured charge for a wide range of RF gun and laser operational parameters within the measurement uncertainties.