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#!/usr/bin/env python3
"""
Cylinders on a rotated 2D lattice
"""
import bornagain as ba
from bornagain import ba_plot as bp, deg, nm
def get_sample():
"""
Returns a sample with cylinders on a substrate, forming a rotated 2D lattice
"""
# Define materials
material_Particle = ba.RefractiveMaterial("Particle", 0.0006, 2e-08)
material_Substrate = ba.RefractiveMaterial("Substrate", 6e-06, 2e-08)
material_Vacuum = ba.RefractiveMaterial("Vacuum", 0, 0)
# Define form factors
ff = ba.Cylinder(3*nm, 3*nm)
# Define particles
particle = ba.Particle(material_Particle, ff)
# Define 2D lattices
lattice = ba.BasicLattice2D(25*nm, 25*nm, 90*deg, 30*deg)
# Define interference functions
iff = ba.Interference2DLattice(lattice)
iff_pdf = ba.Profile2DCauchy(47.7464829276*nm, 15.9154943092*nm,
30*deg)
iff.setDecayFunction(iff_pdf)
# Define particle layouts
layout = ba.ParticleLayout()
layout.addParticle(particle)
layout.setInterference(iff)
layout.setTotalParticleSurfaceDensity(0.0016)
# Define layers
layer_1 = ba.Layer(material_Vacuum)
layer_1.addLayout(layout)
layer_2 = ba.Layer(material_Substrate)
# Define sample
sample = ba.MultiLayer()
sample.addLayer(layer_1)
sample.addLayer(layer_2)
return sample
def get_simulation(sample):
beam = ba.Beam(1e9, 0.1*nm, 0.2*deg)
n = bp.simargs['n']
detector = ba.SphericalDetector(n, -2*deg, 2*deg, n, 0, 2*deg)
simulation = ba.ScatteringSimulation(beam, sample, detector)
return simulation
if __name__ == '__main__':
bp.parse_args(sim_n=200)
sample = get_sample()
simulation = get_simulation(sample)
result = simulation.simulate()
bp.plot_simulation_result(result)
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BornAgain
≻ 20
≻ Documentation ≻ Reference ≻ Sample model ≻ Particle assemblies ≻ 2D lattice ≻ 2D rotated square lattice
