Small-Angle Scattering. Ian W. Hamley. Читать онлайн. Mreadz. MREADZ.COM

Название	Small-Angle Scattering
Автор произведения	Ian W. Hamley
Жанр	Техническая литература
Серия
Издательство	Техническая литература
Год выпуска	0
isbn	9781119768340

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upper R Subscript g Baseline equals StartRoot a squared plus b squared EndRoot slash 2

. For a rod of length L with finite cross‐section the overall radius of gyration, Rg, is related to that of the cross‐section Rc via the expression [7, 11, 12, 14]:

(1.25) upper R Subscript g Superscript 2 Baseline equals upper R Subscript c Superscript 2 Baseline plus StartFraction upper L squared Over 12 EndFraction

The Guinier approximation is useful for systems containing non‐interacting particles (i.e. the structure factor S(q) = 1, see Section 1.5) and is typically valid for q < 1/Rg.

1.5 FORM AND STRUCTURE FACTORS

The total intensity scattered by an ensemble of particles (self‐assembled structures, surfactant or polymer assemblies, colloids, etc.) can be separated into terms depending on intra‐particle and inter‐particle terms (Figure 1.4), which are termed the form factor and structure factor, respectively.

Schematic illustration of the scattering within particles corresponds to form factor while scattering between particles corresponds to structure factor.

Figure 1.4 Scattering within particles (from atoms/components shown as black dots) corresponds to form factor while scattering between particles (separated by vector r_jk) corresponds to structure factor.

For a monodisperse system of spherically symmetric particles (number density np = N/V), the scattering can be written as

(1.26)

where F(q) is the amplitude of scattering from within a particle:

(1.27) upper F left-parenthesis q right-parenthesis equals left pointing angle sigma-summation Underscript i Endscripts a Subscript i Baseline exp left-bracket minus i bold q period bold r right-bracket right pointing angle Subscript upper Omega

which is analogous to an isotropic average over Eq. (1.2).

Equation (1.25) can be separated into intra‐ and inter‐ particle components:

(1.28)

This can be written for the monodisperse ensemble of spherically symmetric particles as

(1.29) upper I left-parenthesis q right-parenthesis equals upper P left-parenthesis q right-parenthesis upper S left-parenthesis q right-parenthesis

Here the form factor is

(1.30) upper P left-parenthesis q right-parenthesis equals sigma-summation Underscript j Endscripts upper F Subscript j Superscript 2 Baseline left-parenthesis q right-parenthesis

and the structure factor is

(1.31)

In a sufficiently dilute system only the form factor needs to be considered. Intermolecular interferences are manifested by the increasing contribution of the structure factor as concentration is increased. In many micellar, biomolecular, and surfactant systems in dilute aqueous solution, structure factor effects may not be observed (over the typical q range accessed in most SAXS measurements). At high concentration, the structure factor is characterized by a series of peaks (due to successive nearest neighbour correlations, next nearest neighbour correlations etc.) the intensity decaying as q increases, oscillating around the average value S(q) = 1. The structure factor is related by a Fourier transform to the radial distribution function g(r):

(1.32) upper S left-parenthesis q right-parenthesis equals 1 plus StartFraction 4 pi upper N Over upper V EndFraction integral Subscript 0 Superscript infinity Baseline g left-parenthesis r right-parenthesis StartFraction sine left-parenthesis italic q r right-parenthesis Over italic q r EndFraction r squared italic d r

where V is the volume of the particle.

Figure 1.5 shows the calculated total intensity within the monodisperse approximation (product of form and structure factors) for spheres of radius R = 30 Å (also hard sphere structure factor radius R_H = 30 Å) at two volume fractions showing the increase in the contribution from the structure factor at low q including the development of a peak at q ≈ 0.1 Å⁻¹.

$Graphs depict the calculated total intensity I(q) = P(q)S(q) in the monodisperse approximation for spheres with radius R = 30 Å and hard sphere structure factor with RHS = 30 Å and volume fraction (a) 0.2, (b) 0.4. The structure factor S(q) has been scaled by a factor of 105 in (a) and 106 in (b) for ease of visualisation.$

Figure 1.5 Calculated total intensity I(q) = P(q)S(q) in the monodisperse approximation for spheres with radius R = 30 Å (polydispersity σ = 3 Å, see Figure 1.19) and hard sphere structure factor with R_HS = 30 Å and volume fraction (a) 0.2, (b) 0.4. The structure factor S(q) has been scaled by a factor of 10⁵ in (a) and 10⁶ in (b) for ease of visualisation.

The

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Small-Angle Scattering. Ian W. Hamley

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1.5 FORM AND STRUCTURE FACTORS