📝 SummarXiv

Abstract

We present simulation of the classical and quantum beam dynamics of an RF photoinjector test bench under development at Joint Institute for Nuclear Research. A 0.63 pC electron bunch is driven from a copper photocathode by a 262 nm ultraviolet laser and accelerated to energies of a few MeV in a 2856 MHz, 1.5-cell RF gun. Using realistic electromagnetic field maps and the ASTRA particle-tracking code, we optimize a Carlsten-style emittance-compensation solenoid to achieve a normalized transverse emittance of 3.2 pi mm mrad downstream of the gun. We also simulate the dynamic of a single-electron Laguerre-Gaussian wave packet carrying l = hbar orbital angular momentum projection in the same RF fields: continuous acceleration reduces its de Broglie wavelength and suppresses transverse spreading by a factor of six compared to free-space propagation over 30 cm. These results confirm the injector design, demonstrate the feasibility of the proposed emittance-compensation scheme, and pave the way to the first experimental demonstration of relativistic vortex electron generation in the few MeV energy range.