| 1 | r""" |
|---|
| 2 | Polydispersity in the bilayer thickness can be applied from the GUI. |
|---|
| 3 | |
|---|
| 4 | Definition |
|---|
| 5 | ---------- |
|---|
| 6 | |
|---|
| 7 | The scattering intensity $I(q)$ is |
|---|
| 8 | |
|---|
| 9 | .. math:: |
|---|
| 10 | |
|---|
| 11 | I(q) = \frac{2\pi P(q)}{\delta q^2} |
|---|
| 12 | |
|---|
| 13 | |
|---|
| 14 | The form factor is |
|---|
| 15 | |
|---|
| 16 | .. math:: |
|---|
| 17 | |
|---|
| 18 | P(q) = \frac{2\Delta\rho^2}{q^2}(1-cos(q\delta)) |
|---|
| 19 | |
|---|
| 20 | |
|---|
| 21 | where $\delta$ is the bilayer thickness. |
|---|
| 22 | |
|---|
| 23 | The 2D scattering intensity is calculated in the same way as 1D, where |
|---|
| 24 | the $q$ vector is defined as |
|---|
| 25 | |
|---|
| 26 | .. math:: |
|---|
| 27 | |
|---|
| 28 | q = \sqrt{q_x^2 + q_y^2} |
|---|
| 29 | |
|---|
| 30 | |
|---|
| 31 | .. figure:: img/lamellar_1d.jpg |
|---|
| 32 | |
|---|
| 33 | 1D plot using the default values (w/1000 data point). |
|---|
| 34 | |
|---|
| 35 | |
|---|
| 36 | References |
|---|
| 37 | ---------- |
|---|
| 38 | |
|---|
| 39 | F Nallet, R Laversanne, and D Roux, J. Phys. II France, 3, (1993) 487-502 |
|---|
| 40 | |
|---|
| 41 | also in J. Phys. Chem. B, 105, (2001) 11081-11088 |
|---|
| 42 | |
|---|
| 43 | |
|---|
| 44 | """ |
|---|
| 45 | |
|---|
| 46 | from numpy import inf |
|---|
| 47 | |
|---|
| 48 | name = "lamellar" |
|---|
| 49 | title = "Lyotropic lamellar phase with uniform SLD and random distribution" |
|---|
| 50 | description = """\ |
|---|
| 51 | [Dilute Lamellar Form Factor](from a lyotropic lamellar phase) |
|---|
| 52 | I(q)= 2*pi*P(q)/(delta *q^(2)), where |
|---|
| 53 | P(q)=2*(contrast/q)^(2)*(1-cos(q*delta))^(2)) |
|---|
| 54 | thickness = layer thickness |
|---|
| 55 | sld = layer scattering length density |
|---|
| 56 | sld_solvent = solvent scattering length density |
|---|
| 57 | background = incoherent background |
|---|
| 58 | scale = scale factor |
|---|
| 59 | """ |
|---|
| 60 | category = "shape:lamellae" |
|---|
| 61 | |
|---|
| 62 | # ["name", "units", default, [lower, upper], "type","description"], |
|---|
| 63 | parameters = [["sld", "1e-6/Ang^2", 1, [-inf, inf], "", |
|---|
| 64 | "Layer scattering length density" ], |
|---|
| 65 | ["solvent_sld", "1e-6/Ang^2", 6, [-inf, inf], "", |
|---|
| 66 | "Solvent scattering length density" ], |
|---|
| 67 | ["thickness", "Ang", 50, [0, inf], "volume","Bilayer thickness" ], |
|---|
| 68 | ] |
|---|
| 69 | |
|---|
| 70 | |
|---|
| 71 | # No volume normalization despite having a volume parameter |
|---|
| 72 | # This should perhaps be volume normalized? |
|---|
| 73 | form_volume = """ |
|---|
| 74 | return 1.0; |
|---|
| 75 | """ |
|---|
| 76 | |
|---|
| 77 | Iq = """ |
|---|
| 78 | const double sub = sld - solvent_sld; |
|---|
| 79 | const double qsq = q*q; |
|---|
| 80 | // Original expression |
|---|
| 81 | //return 4.0e-4*M_PI*sub*sub/qsq * (1.0-cos(q*thickness)) / (thickness*qsq); |
|---|
| 82 | // const double alpha = fmod(q*thickness+0.1, 2.0*M_PI)-0.1; |
|---|
| 83 | // Use small angle fix 1-cos(theta) = 2 sin^2(theta/2) |
|---|
| 84 | const double sinq2 = sin(0.5*q*thickness); |
|---|
| 85 | return 4.0e-4*M_PI*sub*sub/qsq * 2.0*sinq2*sinq2 / (thickness*qsq); |
|---|
| 86 | """ |
|---|
| 87 | |
|---|
| 88 | Iqxy = """ |
|---|
| 89 | return Iq(sqrt(qx*qx+qy*qy), IQ_PARAMETERS); |
|---|
| 90 | """ |
|---|
| 91 | |
|---|
| 92 | # ER defaults to 0.0 |
|---|
| 93 | # VR defaults to 1.0 |
|---|
| 94 | |
|---|
| 95 | demo = dict(scale=1, background=0, |
|---|
| 96 | sld=6, solvent_sld=1, |
|---|
| 97 | thickness=40, |
|---|
| 98 | thickness_pd=0.2, thickness_pd_n=40) |
|---|
| 99 | oldname = 'LamellarModel' |
|---|
| 100 | oldpars = dict(sld='sld_bi', solvent_sld='sld_sol', thickness='bi_thick') |
|---|
| 101 | |
|---|
