[8007311] | 1 | r""" |
---|
| 2 | Definition |
---|
| 3 | ---------- |
---|
[adc753d] | 4 | |
---|
[40a87fa] | 5 | This model provides the form factor for a circular cylinder with a |
---|
| 6 | core-shell scattering length density profile. Thus this is a variation |
---|
| 7 | of a core-shell cylinder or disc where the shell on the walls and ends |
---|
| 8 | may be of different thicknesses and scattering length densities. The form |
---|
| 9 | factor is normalized by the particle volume. |
---|
[8007311] | 10 | |
---|
| 11 | |
---|
| 12 | .. figure:: img/core_shell_bicelle_geometry.png |
---|
| 13 | |
---|
[a0fee3b] | 14 | Schematic cross-section of bicelle. Note however that the model here |
---|
| 15 | calculates for rectangular, not curved, rims as shown below. |
---|
| 16 | |
---|
| 17 | .. figure:: img/core_shell_bicelle_parameters.png |
---|
| 18 | |
---|
| 19 | Cross section of cylindrical symmetry model used here. Users will have |
---|
| 20 | to decide how to distribute "heads" and "tails" between the rim, face |
---|
| 21 | and core regions in order to estimate appropriate starting parameters. |
---|
[8007311] | 22 | |
---|
[adc753d] | 23 | Given the scattering length densities (sld) $\rho_c$, the core sld, $\rho_f$, |
---|
| 24 | the face sld, $\rho_r$, the rim sld and $\rho_s$ the solvent sld, the |
---|
| 25 | scattering length density variation along the cylinder axis is: |
---|
| 26 | |
---|
| 27 | .. math:: |
---|
| 28 | |
---|
| 29 | \rho(r) = |
---|
| 30 | \begin{cases} |
---|
| 31 | &\rho_c \text{ for } 0 \lt r \lt R; -L \lt z\lt L \\[1.5ex] |
---|
| 32 | &\rho_f \text{ for } 0 \lt r \lt R; -(L+2t) \lt z\lt -L; |
---|
| 33 | L \lt z\lt (L+2t) \\[1.5ex] |
---|
| 34 | &\rho_r\text{ for } 0 \lt r \lt R; -(L+2t) \lt z\lt -L; L \lt z\lt (L+2t) |
---|
| 35 | \end{cases} |
---|
| 36 | |
---|
| 37 | The form factor for the bicelle is calculated in cylindrical coordinates, where |
---|
| 38 | $\alpha$ is the angle between the $Q$ vector and the cylinder axis, to give: |
---|
| 39 | |
---|
| 40 | .. math:: |
---|
| 41 | |
---|
[041bc75] | 42 | I(Q,\alpha) = \frac{\text{scale}}{V_t} \cdot |
---|
[adc753d] | 43 | F(Q,\alpha)^2 + \text{background} |
---|
[416f5c7] | 44 | |
---|
[adc753d] | 45 | where |
---|
| 46 | |
---|
| 47 | .. math:: |
---|
| 48 | |
---|
[416f5c7] | 49 | \begin{align} |
---|
| 50 | F(Q,\alpha) = &\bigg[ |
---|
[b829b16] | 51 | (\rho_c - \rho_f) V_c \frac{2J_1(QRsin \alpha)}{QRsin\alpha}\frac{sin(QLcos\alpha/2)}{Q(L/2)cos\alpha} \\ |
---|
| 52 | &+(\rho_f - \rho_r) V_{c+f} \frac{2J_1(QRsin\alpha)}{QRsin\alpha}\frac{sin(Q(L/2+t_f)cos\alpha)}{Q(L/2+t_f)cos\alpha} \\ |
---|
| 53 | &+(\rho_r - \rho_s) V_t \frac{2J_1(Q(R+t_r)sin\alpha)}{Q(R+t_r)sin\alpha}\frac{sin(Q(L/2+t_f)cos\alpha)}{Q(L/2+t_f)cos\alpha} |
---|
[adc753d] | 54 | \bigg] |
---|
| 55 | \end{align} |
---|
| 56 | |
---|
| 57 | where $V_t$ is the total volume of the bicelle, $V_c$ the volume of the core, |
---|
| 58 | $V_{c+f}$ the volume of the core plus the volume of the faces, $R$ is the radius |
---|
| 59 | of the core, $L$ the length of the core, $t_f$ the thickness of the face, $t_r$ |
---|
| 60 | the thickness of the rim and $J_1$ the usual first order bessel function. |
---|
| 61 | |
---|
[8007311] | 62 | The output of the 1D scattering intensity function for randomly oriented |
---|
[adc753d] | 63 | cylinders is then given by integrating over all possible $\theta$ and $\phi$. |
---|
[8007311] | 64 | |
---|
| 65 | The *theta* and *phi* parameters are not used for the 1D output. |
---|
| 66 | Our implementation of the scattering kernel and the 1D scattering intensity |
---|
| 67 | use the c-library from NIST. |
---|
| 68 | |
---|
[2f0c07d] | 69 | .. figure:: img/cylinder_angle_definition.jpg |
---|
[8007311] | 70 | |
---|
[2f0c07d] | 71 | Definition of the angles for the oriented core shell bicelle tmodel. |
---|
[8007311] | 72 | |
---|
| 73 | |
---|
| 74 | References |
---|
| 75 | ---------- |
---|
| 76 | |
---|
[adc753d] | 77 | .. [#] D Singh (2009). *Small angle scattering studies of self assembly in |
---|
| 78 | lipid mixtures*, John's Hopkins University Thesis (2009) 223-225. `Available |
---|
| 79 | from Proquest <http://search.proquest.com/docview/304915826?accountid |
---|
| 80 | =26379>`_ |
---|
[b0c4271] | 81 | |
---|
| 82 | Authorship and Verification |
---|
| 83 | ---------------------------- |
---|
| 84 | |
---|
| 85 | * **Author:** NIST IGOR/DANSE **Date:** pre 2010 |
---|
[adc753d] | 86 | * **Last Modified by:** Paul Butler **Date:** September 30, 2016 |
---|
| 87 | * **Last Reviewed by:** Richard Heenan **Date:** October 5, 2016 |
---|
[8007311] | 88 | """ |
---|
| 89 | |
---|
| 90 | from numpy import inf, sin, cos |
---|
| 91 | |
---|
| 92 | name = "core_shell_bicelle" |
---|
| 93 | title = "Circular cylinder with a core-shell scattering length density profile.." |
---|
| 94 | description = """ |
---|
[a0fee3b] | 95 | P(q,alpha)= (scale/Vs)*f(q)^(2) + bkg, where: |
---|
| 96 | f(q)= Vt(sld_rim - sld_solvent)* sin[qLt.cos(alpha)/2] |
---|
| 97 | /[qLt.cos(alpha)/2]*J1(qRout.sin(alpha)) |
---|
| 98 | /[qRout.sin(alpha)]+ |
---|
| 99 | (sld_core-sld_face)*Vc*sin[qLcos(alpha)/2][[qL |
---|
| 100 | *cos(alpha)/2]*J1(qRc.sin(alpha)) |
---|
| 101 | /qRc.sin(alpha)]+ |
---|
| 102 | (sld_face-sld_rim)*(Vc+Vf)*sin[q(L+2.thick_face). |
---|
| 103 | cos(alpha)/2][[q(L+2.thick_face)*cos(alpha)/2]* |
---|
| 104 | J1(qRc.sin(alpha))/qRc.sin(alpha)] |
---|
[8007311] | 105 | |
---|
| 106 | alpha:is the angle between the axis of |
---|
| 107 | the cylinder and the q-vector |
---|
[a0fee3b] | 108 | Vt = pi.(Rc + thick_rim)^2.Lt : total volume |
---|
| 109 | Vc = pi.Rc^2.L :the volume of the core |
---|
| 110 | Vf = 2.pi.Rc^2.thick_face |
---|
| 111 | Rc = radius: is the core radius |
---|
[8007311] | 112 | L: the length of the core |
---|
[a0fee3b] | 113 | Lt = L + 2.thick_face: total length |
---|
| 114 | Rout = radius + thick_rim |
---|
| 115 | sld_core, sld_rim, sld_face:scattering length |
---|
| 116 | densities within the particle |
---|
[aad336c] | 117 | sld_solvent: the scattering length density |
---|
[8007311] | 118 | of the solvent |
---|
| 119 | bkg: the background |
---|
| 120 | J1: the first order Bessel function |
---|
| 121 | theta: axis_theta of the cylinder |
---|
| 122 | phi: the axis_phi of the cylinder... |
---|
| 123 | """ |
---|
| 124 | category = "shape:cylinder" |
---|
| 125 | |
---|
| 126 | # pylint: disable=bad-whitespace, line-too-long |
---|
| 127 | # ["name", "units", default, [lower, upper], "type", "description"], |
---|
| 128 | parameters = [ |
---|
[416f5c7] | 129 | ["radius", "Ang", 80, [0, inf], "volume", "Cylinder core radius"], |
---|
[2222134] | 130 | ["thick_rim", "Ang", 10, [0, inf], "volume", "Rim shell thickness"], |
---|
| 131 | ["thick_face", "Ang", 10, [0, inf], "volume", "Cylinder face thickness"], |
---|
[416f5c7] | 132 | ["length", "Ang", 50, [0, inf], "volume", "Cylinder length"], |
---|
[42356c8] | 133 | ["sld_core", "1e-6/Ang^2", 1, [-inf, inf], "sld", "Cylinder core scattering length density"], |
---|
| 134 | ["sld_face", "1e-6/Ang^2", 4, [-inf, inf], "sld", "Cylinder face scattering length density"], |
---|
| 135 | ["sld_rim", "1e-6/Ang^2", 4, [-inf, inf], "sld", "Cylinder rim scattering length density"], |
---|
| 136 | ["sld_solvent", "1e-6/Ang^2", 1, [-inf, inf], "sld", "Solvent scattering length density"], |
---|
[8007311] | 137 | ["theta", "degrees", 90, [-inf, inf], "orientation", "In plane angle"], |
---|
| 138 | ["phi", "degrees", 0, [-inf, inf], "orientation", "Out of plane angle"], |
---|
| 139 | ] |
---|
| 140 | |
---|
| 141 | # pylint: enable=bad-whitespace, line-too-long |
---|
| 142 | |
---|
[40a87fa] | 143 | source = ["lib/Si.c", "lib/polevl.c", "lib/sas_J1.c", "lib/gauss76.c", |
---|
| 144 | "core_shell_bicelle.c"] |
---|
[8007311] | 145 | |
---|
| 146 | demo = dict(scale=1, background=0, |
---|
| 147 | radius=20.0, |
---|
[2222134] | 148 | thick_rim=10.0, |
---|
| 149 | thick_face=10.0, |
---|
[8007311] | 150 | length=400.0, |
---|
[aad336c] | 151 | sld_core=1.0, |
---|
| 152 | sld_face=4.0, |
---|
| 153 | sld_rim=4.0, |
---|
| 154 | sld_solvent=1.0, |
---|
[8007311] | 155 | theta=90, |
---|
| 156 | phi=0) |
---|
| 157 | |
---|
| 158 | qx, qy = 0.4 * cos(90), 0.5 * sin(0) |
---|