Multi-objective Bayesian optimisation of a double-layer target for quasi-monoenergetic TNSA protons

Abstract

We carry out a six-parameter multi-objective Bayesian optimisation of a carbon--hydrogen double-layer target for target-normal-sheath proton acceleration. The campaign consists of 80 two-dimensional EPOCH simulations with the laser amplitude a0, pulse duration τ, carbon-layer thickness L1, hydrogen-layer density N2, hydrogen-layer thickness L2 and hydrogen-layer radius rp as input variables. Each final proton spectrum is scored by the peak energy, the charge fraction inside a 10\% peak-energy window and the charge in that window. Among the Pareto-set evaluations, the cases with peak energies between 64 and 71 MeV occur near a0=30, τ=45 fs, L1=0.3\,μ m, L2=30 nm and rp=0.15\,μ m. Along this branch, increasing N2 raises the in-window charge and increases the bandwidth. The small rear-layer radius keeps the proton source within the flat central region of the transverse sheath field, where the accelerating field is nearly uniform. A 3D calculation is performed for the intermediate-density case N2=11.85\,nc, which balances bandwidth and in-window charge along this branch. The corresponding 2D spectrum has E peak=67.4 MeV and ΔE/E=18.8\%, whereas the 3D spectrum has E peak=34.1 MeV and ΔE/E=7.0\%. The lower 3D peak energy and narrower bandwidth are associated with an earlier decay of the rear-sheath field and an earlier saturation of the proton peak energy, and the quasi-monoenergetic peak is retained in 3D.