Added plotting of the roton instability boundary for tilted dipoles.

2024-11-06 16:16:50 +01:00 · 2024-11-06 16:16:50 +01:00 · dcd13f9297
commit dcd13f9297
parent 4ad098ae9a
1 changed files with 76 additions and 0 deletions
--- a/Quasi2DBogoliubovSpectrum.m
+++ b/Quasi2DBogoliubovSpectrum.m
@ -286,6 +286,82 @@ xlabel('$na_{dd}^2$','fontsize',16,'interpreter','latex');
 ylabel('$a_s/a_{dd}$','fontsize',16,'interpreter','latex');
 title('Roton instability boundary','fontsize',16,'interpreter','latex')
 %% Roton instability boundary for tilted dipoles
 wz           = 2 * pi * 72.4;                                                                   % Trap frequency in the tight confinement direction
 lz           = sqrt(PlanckConstantReduced/(Dy164Mass * wz));                                    % Defining a harmonic oscillator length
 gs           = 4 * pi * PlanckConstantReduced^2/Dy164Mass * as;                                 % Contact interaction strength
 add          = VacuumPermeability*DyMagneticMoment^2*Dy164Mass/(12*pi*PlanckConstantReduced^2); % Dipole length
 gdd          = VacuumPermeability*DyMagneticMoment^2/3;
 nadd2s       = 0.05:0.001:0.25;
 as_to_add    = 0.76:0.001:0.81;
 var_widths   = zeros(length(as_to_add), length(nadd2s));
 x0           = 5;
 Aineq        = []; 
 Bineq        = []; 
 Aeq          = []; 
 Beq          = [];
 lb           = [1]; 
 ub           = [10];
 nonlcon      = [];
 fminconopts  = optimoptions(@fmincon,'Display','off', 'StepTolerance', 1.0000e-11, 'MaxIterations',1500);
 for idx = 1:length(nadd2s)
    for jdx = 1:length(as_to_add)
        AtomNumberDensity      = nadd2s(idx) / add^2;                                                             % Areal density of atoms
        as                     = (as_to_add(jdx) * add);                                                          % Scattering length
        TotalEnergyPerParticle = @(x) computeTotalEnergyPerParticle(x, as, AtomNumberDensity, wz, lz, gs, add, gdd, PlanckConstantReduced);
        sigma                  = fmincon(TotalEnergyPerParticle, x0, Aineq, Bineq, Aeq, Beq, lb, ub, nonlcon, fminconopts);
        var_widths(jdx, idx)   = sigma;
    end
 end
 % ====================================================================================================================================================== %
 alpha                = 45;                                                                               % Polar angle of dipole moment
 phi                  = 0;                                                                               % Azimuthal angle of momentum vector
 k                    = linspace(0, 2.25e6, 1000);                                                       % Vector of magnitudes of k vector
 instability_boundary = zeros(length(as_to_add), length(nadd2s));
 for idx = 1:length(nadd2s)
    for jdx = 1:length(as_to_add)
        AtomNumberDensity = nadd2s(idx) / add^2;                                                             % Areal density of atoms
        as                = (as_to_add(jdx) * add);                                                          % Scattering length
        eps_dd            = add/as;                                                                          % Relative interaction strength
        gs                = 4 * pi * PlanckConstantReduced^2/Dy164Mass * as;                                 % Contact interaction strength
        gdd               = VacuumPermeability*DyMagneticMoment^2/3;
        MeanWidth         = var_widths(jdx, idx) * lz;                                                       % Mean width of Gaussian ansatz
        [Go,gamma4,Fka,Ukk] = computePotentialInMomentumSpace(k, gs, gdd, MeanWidth, alpha, phi);            % DDI potential in k-space
        % == Quantum Fluctuations term == %
        gammaQF           = (32/3) * gs * (as^3/pi)^(1/2) * (1 + ((3/2) * eps_dd^2));
        gamma5            = sqrt(2/5) / (sqrt(pi) * MeanWidth)^(3/2);
        gQF               = gamma5 * gammaQF;
        % == Dispersion relation == %
        DeltaK            = ((PlanckConstantReduced^2 .* k.^2) ./ (2 * Dy164Mass)) + ((2 * AtomNumberDensity) .* Ukk) + (3 * gQF * AtomNumberDensity^(3/2));
        EpsilonK          = sqrt(((PlanckConstantReduced^2 .* k.^2) ./ (2 * Dy164Mass)) .* DeltaK); 
        instability_boundary(jdx, idx)  = ~isreal(EpsilonK);
    end
 end
 nadd2s_from_figure     = [0.04974, 0.05383, 0.05655, 0.06609, 0.06916, 0.07291, 0.07836, 0.08517, 0.09063, 0.0978, 0.10459, 0.11345, 0.11822, 0.12231, 0.12674, 0.13117, 0.13560, 0.14003, 0.14548, 0.15127, 0.15775, 0.16660, 0.17546, 0.18364, 0.19557, 0.20579, 0.21839, 0.23850, 0.25144];
 as_to_add_from_figure  = [0.76383, 0.76766, 0.76974, 0.77543, 0.77675, 0.77828, 0.78003, 0.78178, 0.78288, 0.7840, 0.78474, 0.78540, 0.78562, 0.78572, 0.78583, 0.78583, 0.78583, 0.78583, 0.78567, 0.78551, 0.78529, 0.78485, 0.78441, 0.78386, 0.78310, 0.78233, 0.78135, 0.77970, 0.77861];
 figure(6)
 clf
 set(gcf,'Position',[50 50 950 750])
 imagesc(nadd2s, as_to_add, instability_boundary);  % Specify x and y data for axes
 hold on 
 plot(nadd2s_from_figure, as_to_add_from_figure, 'r*-', 'LineWidth', 2);  % Plot the curve (red line)
 set(gca, 'YDir', 'normal');              % Correct the y-axis direction
 colorbar;                                % Add a colorbar
 xlabel('$na_{dd}^2$','fontsize',16,'interpreter','latex');
 ylabel('$a_s/a_{dd}$','fontsize',16,'interpreter','latex');
 title('Roton instability boundary','fontsize',16,'interpreter','latex')
 %%
 function [Go,gamma4,Fka,Ukk] = computePotentialInMomentumSpace(k, gs, gdd, MeanWidth, alpha, phi)
   Go                        = sqrt(pi) * (k * MeanWidth/sqrt(2)) .* exp((k * MeanWidth/sqrt(2)).^2) .* erfc((k * MeanWidth/sqrt(2)));