Examples/Modules/gaussian_beam/PICMI_inputs_gaussian_beam.py


1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77

from pywarpx import picmi
#from warp import picmi

constants = picmi.constants

nx = 32
ny = 32
nz = 32

xmin = -2.
xmax = +2.
ymin = -2.
ymax = +2.
zmin = -2.
zmax = +2.

number_sim_particles = 32768
total_charge = 8.010883097437485e-07

beam_rms_size = 0.25
electron_beam_divergence = -0.04*constants.c

em_order = 3

grid = picmi.Cartesian3DGrid(number_of_cells = [nx, ny, nz],
                             lower_bound = [xmin, ymin, zmin],
                             upper_bound = [xmax, ymax, zmax],
                             lower_boundary_conditions = ['periodic', 'periodic', 'open'],
                             upper_boundary_conditions = ['periodic', 'periodic', 'open'],
                             lower_boundary_conditions_particles = ['periodic', 'periodic', 'absorbing'],
                             upper_boundary_conditions_particles = ['periodic', 'periodic', 'absorbing'],
                             warpx_max_grid_size=16)

solver = picmi.ElectromagneticSolver(grid = grid,
                                     cfl = 1.,
                                     stencil_order=[em_order,em_order,em_order])

electron_beam = picmi.GaussianBunchDistribution(n_physical_particles = total_charge/constants.q_e,
                                                rms_bunch_size = [beam_rms_size, beam_rms_size, beam_rms_size],
                                                velocity_divergence = [electron_beam_divergence, electron_beam_divergence, electron_beam_divergence])

proton_beam = picmi.GaussianBunchDistribution(n_physical_particles = total_charge/constants.q_e,
                                              rms_bunch_size = [beam_rms_size, beam_rms_size, beam_rms_size])

electrons = picmi.Species(particle_type='electron', name='electrons', initial_distribution=electron_beam)
protons = picmi.Species(particle_type='proton', name='protons', initial_distribution=proton_beam)

field_diag1 = picmi.FieldDiagnostic(name = 'diag1',
                                    grid = grid,
                                    period = 10,
                                    data_list = ['E', 'B', 'J', 'part_per_cell'],
                                    write_dir = '.',
                                    warpx_file_prefix = 'Python_gaussian_beam_plt')

part_diag1 = picmi.ParticleDiagnostic(name = 'diag1',
                                      period = 10,
                                      species = [electrons, protons],
                                      data_list = ['weighting', 'momentum'])

sim = picmi.Simulation(solver = solver,
                       max_steps = 10,
                       verbose = 1,
                       warpx_current_deposition_algo = 'direct',
                       warpx_use_filter = 0)

sim.add_species(electrons, layout=picmi.PseudoRandomLayout(n_macroparticles=number_sim_particles))
sim.add_species(protons, layout=picmi.PseudoRandomLayout(n_macroparticles=number_sim_particles))

sim.add_diagnostic(field_diag1)
sim.add_diagnostic(part_diag1)

# write_inputs will create an inputs file that can be used to run
# with the compiled version.
#sim.write_input_file(file_name = 'inputs_from_PICMI')

# Alternatively, sim.step will run WarpX, controlling it from Python
sim.step()