1; useful_constants; % 87Rb D1 line % % m=-2 m=-1 m=0 m=1 m=2 % ---- ---- ---- ---- ---- |P,F=2> % % ---- ---- ---- |P,F=1> % m=-1 m=0 m=1 % % % % % % m=-2 m=-1 m=0 m=1 m=2 % ---- ---- ---- ---- ---- |S,F=2> % % ---- ---- ---- |S,F=1> % m=-1 m=0 m=1 B_field=.3; w_hpf_ground=6834; w_hpf_exited=817; w_sf2 = w_hpf_ground; % Distance from |S,F=1> to |S,F=2> w_pf1 =1e9; % something big Distance from |S,F=1> to |P,F=1> w_pf2 = w_pf1+w_hpf_exited; %Distance from |S,F=1> to |P,F=2> gmg=.7; % gyro magnetic ration for ground level gme=.0; % gyro magnetic ration for exited level % CHECKME %bottom level |F=1> levels( 1)=struct( "ang_momentum", 0, "total_momentum", 1, "m", -1, "energy", 0, "gm", -gmg); levels( 2)=struct( "ang_momentum", 0, "total_momentum", 1, "m", 0, "energy", 0, "gm", -gmg); levels( 3)=struct( "ang_momentum", 0, "total_momentum", 1, "m", 1, "energy", 0, "gm", -gmg); %second bottom level |F=2> levels( 4)=struct( "ang_momentum", 0, "total_momentum", 2, "m", -2, "energy", w_sf2, "gm", gmg); levels( 5)=struct( "ang_momentum", 0, "total_momentum", 2, "m", -1, "energy", w_sf2, "gm", gmg); levels( 6)=struct( "ang_momentum", 0, "total_momentum", 2, "m", 0, "energy", w_sf2, "gm", gmg); levels( 7)=struct( "ang_momentum", 0, "total_momentum", 2, "m", 1, "energy", w_sf2, "gm", gmg); levels( 8)=struct( "ang_momentum", 0, "total_momentum", 2, "m", 2, "energy", w_sf2, "gm", gmg); % first exited level |F=1> levels( 9)=struct( "ang_momentum", 1, "total_momentum", 1, "m", -1, "energy", w_pf1, "gm", -gme); levels(10)=struct( "ang_momentum", 1, "total_momentum", 1, "m", 0, "energy", w_pf1, "gm", -gme); levels(11)=struct( "ang_momentum", 1, "total_momentum", 1, "m", 1, "energy", w_pf1, "gm", -gme); % second exited level |F=2> %levels(12)=struct( "ang_momentum", 1, "total_momentum", 2, "m", -2, "energy", w_pf2, "gm", gme); %levels(13)=struct( "ang_momentum", 1, "total_momentum", 2, "m", -1, "energy", w_pf2, "gm", gme); %levels(14)=struct( "ang_momentum", 1, "total_momentum", 2, "m", 0, "energy", w_pf2, "gm", gme); %levels(15)=struct( "ang_momentum", 1, "total_momentum", 2, "m", 1, "energy", w_pf2, "gm", gme); %levels(16)=struct( "ang_momentum", 1, "total_momentum", 2, "m", 2, "energy", w_pf2, "gm", gme); Nlevels=size(levels)(2); H0=zeros(Nlevels); energy = [1:Nlevels].*0; ang_momentum = [1:Nlevels].*0; total_momentum = [1:Nlevels].*0; m = [1:Nlevels].*0; gm = [1:Nlevels].*0; for i=1:Nlevels energy(i) = levels(i).energy; ang_momentum(i) = levels(i).ang_momentum; total_momentum(i) = levels(i).total_momentum; m(i) = levels(i).m; gm(i) = levels(i).gm; endfor H0=diag(energy)*hbar; dipole_elements.left = zeros(Nlevels); dipole_elements.right = zeros(Nlevels); dipole_elements.linear = zeros(Nlevels); % define dipole elements for transition from level j->k for j=1:Nlevels for k=1:Nlevels if ( abs(ang_momentum(j) - ang_momentum(k)) == 1) %transition allowed for L =L' +/- 1 % but they correct within a factor, but not sign if ( ( H0(j,j) < H0(k,k)) ) de=dipole_elementRb87D1line(... total_momentum(j),m(j), ... total_momentum(k),m(k) ... ); dipole_elements.left(j,k) = de.left; dipole_elements.right(j,k) = de.right; dipole_elements.linear(j,k) = de.linear; endif endif endfor endfor dipole_elements.linear+=dipole_elements.linear'; dipole_elements.left+=dipole_elements.left'; dipole_elements.right+=dipole_elements.right'; maximum_dipole_elements=dipole_elements.linear + dipole_elements.left + dipole_elements.right; %defasing matrix g_deph=0; g_dephasing=zeros(Nlevels); % dephasing only for non zero dipole elements (am I right?) g_dephasing=g_deph*(abs(maximum_dipole_elements) != 0); % decay matrix g(i,j) correspnds to decay from i-->j gamma=6; g_decay=zeros(Nlevels); for i=1:Nlevels for j=1:Nlevels if ( H0(i,i) > H0(j,j) ) % only upper levels decaying and decay is always positive g_decay(i,j)=gamma * abs( maximum_dipole_elements(i,j) ); endif endfor endfor % ground level mixing need to be artificial gamma_hpf=.001; for i=1:Nlevels for j=1:Nlevels if ( abs( H0(i,i) - H0(j,j)) == w_hpf_ground*hbar ) % ground hyperfine are mixed together g_decay(i,j)=gamma_hpf; endif endfor endfor % apply B field Zeeman splitting energy+=B_field * ( gm .* m); % convert frequency to energy units H0=diag(energy)*hbar; % vim: ts=2:sw=2:fdm=indent