# Maximum number of time steps max_step = 240 # number of grid points amr.n_cell = 352 # Maximum allowable size of each subdomain in the problem domain; # this is used to decompose the domain for parallel calculations. amr.max_grid_size = 32 # Maximum level in hierarchy (for now must be 0, i.e., one level in total) amr.max_level = 0 # Geometry geometry.dims = 1 geometry.prob_lo = -15.e-6 # physical domain geometry.prob_hi = 15.e-6 boundary.field_lo = pec boundary.field_hi = pec warpx.serialize_initial_conditions = 1 # Verbosity warpx.verbose = 1 # Algorithms algo.current_deposition = esirkepov warpx.use_filter = 0 # CFL warpx.cfl = 0.9 # Order of particle shape factors algo.particle_shape = 1 # Laser lasers.names = laser1 laser1.profile = Gaussian laser1.position = 0.e-6 0.e-6 0.e-6 # This point is on the laser plane laser1.direction = 0. 0. 1. # The plane normal direction laser1.polarization = 1. 1. 0. # The main polarization vector laser1.e_max = 4.e12 # Maximum amplitude of the laser field (in V/m) laser1.wavelength = 1.0e-6 # The wavelength of the laser (in meters) laser1.profile_waist = 5.e-6 # The waist of the laser (in meters) laser1.profile_duration = 10.e-15 # The duration of the laser (in seconds) laser1.profile_t_peak = 24.e-15 # The time at which the laser reaches its peak (in seconds) laser1.profile_focal_distance = 13.109e-6 # Focal distance from the antenna (in meters) # With this focal distance the laser is at focus # at the end of the simulation. # Diagnostics diagnostics.diags_names = diag1 openpmd diag1.intervals = 20 diag1.diag_type = Full openpmd.intervals = 20 openpmd.diag_type = Full openpmd.format = openpmd # Moving window warpx.do_moving_window = 1 warpx.moving_window_dir = z warpx.moving_window_v = 1.0 # in units of the speed of light warpx.start_moving_window_step = 20 warpx.end_moving_window_step = 200