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simulate_josephson_spinorbitactive.m
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simulate_josephson_spinorbitactive.m
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% This script simulates the proximity effect in a normal metal connected
% to two superconductors with a constant phase difference between them.
% It is assumed that the interfaces are spin-active, and the normal metal
% has a Rashba-Dresselhaus coupling in the xy-plane.
%
% Written by Jabir Ali Ouassou <[email protected]>
% Created 2015-05-22
% Updated 2015-05-22
function simulate_josephson_spinorbitactive(phase_difference, interface_polarization, interface_phase, interface_angle_left, interface_angle_right, spinorbit_strength, spinorbit_angle)
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% DEFINE PARAMETERS FOR THE SIMULATION
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% Vectors of positions and energies that will be used in the simulation
positions = linspace(0.0, 1.0, 100);
energies = linspace(0.0, 2.0, 50);
% Filename where results will be stored
output = 'simulate_josephson_spinorbitactive.dat';
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% PREPARATIONS FOR THE SIMULATION
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% Make sure that all required classes and methods are in the current path
initialize;
% Create two superconductors with 'phase_difference' between them
s1 = Superconductor([0], energies, 1, 0.2);
s1.complex = true;
s1.phase_set(-phase_difference/2);
s2 = Superconductor([0], energies, 1, 0.2);
s2.complex = true;
s2.phase_set(+phase_difference/2);
% Create a normal metal connected to the superconductors above
m = Ferromagnet(positions, energies, 1, [0,0,0], SpinVector.RashbaDresselhaus(spinorbit_strength, spinorbit_angle));
m.spinactive = 1;
m.interface_left = 5;
m.interface_right = 5;
m.magnetization_left = [cos(interface_angle_left), sin(interface_angle_left), 0];
m.magnetization_right = [cos(interface_angle_right), sin(interface_angle_right), 0];
m.polarization_left = interface_polarization;
m.polarization_right = interface_polarization;
m.phaseshift_left = interface_phase;
m.phaseshift_right = interface_phase;
m.update_boundary_left(s1);
m.update_boundary_right(s2);
% This enables or disables various debugging options
m.delay = 0;
m.debug = 1;
m.plot = 0;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% PERFORM THE SIMULATION
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% Update the internal state of the metal
m.update;
% Plot the results
figure;
m.plot_dos_surf;
figure;
m.plot_dos_center;
% Save the results of the simulation
save(output);
end