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Dynamic Structure Factor and Diffusion. Outline FDynamic structure factor FDiffusion FDiffusion coefficient FHydrodynamic radius FDiffusion of rodlike.

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Presentation on theme: "Dynamic Structure Factor and Diffusion. Outline FDynamic structure factor FDiffusion FDiffusion coefficient FHydrodynamic radius FDiffusion of rodlike."— Presentation transcript:

1 Dynamic Structure Factor and Diffusion

2 Outline FDynamic structure factor FDiffusion FDiffusion coefficient FHydrodynamic radius FDiffusion of rodlike molecules FConcentration effects

3 Dynamic Structure Factors single-particle structure factor is zero at low concentrations

4 Dynamic Structure Factor and Transition Probability The particle moves from r’ at t = 0 to r at t =  with a transition probability of P(r, r’;  ). S 1 (k,  ) is the Fourier transform of P(r, r’;  ). DLS gives S 1 (k,  ).

5 Diffusion of Particles transition probability diffusion coefficient

6 Mean Square Displacement t in log scale  in log scale slope = 1 mean square displacement

7 Diffusion Equation concentration at t = 0,

8 Structure Factor by a Diffusing Particle decay rate

9 How to Estimate Diffusion Coefficient 1. Prepare a plot of  as a function of k 2. 2. If all the points fall on a straight line, the slope gives D. It can be shown thatis equivalent to (diffusional)

10 Stokes-Einstein Equation Nernst-Einstein Equation Stokes Equation Stokes-Einstein Equation Stokes radius friction coefficient

11 Hydrodynamic Radius hydrodynamic radius A suspension of R H has the same diffusion coefficient as that of a sphere of radius R H.

12 Hydrodynamic Interactions The friction a polymer chain of N beads receives from the solvent is much smaller than the total friction N independent beads receive. The motion of bead 1 causes nearby solvent molecules to move in the same direction, facilitating the motion of bead 2.

13 Hydrodynamic Radius of a Polymer Chain For a Gaussian chain,

14 Hydrodynamic Radius of Polymer PS in o-fluorotoluene  -MPS in cyclohexane, 30.5 °C good solventtheta solvent

15 Diffusion of Rodlike Molecules

16 Concentration Effects If you trace the red particle, its displacement is smaller because of collision. The collision spreads the concentration fluctuations more quickly compared with the absence of collisions.

17 Self-Diffusion Coefficients and Mutual Diffusion Coefficients mutual diffusion coefficients self-diffusion coefficients

18 Self-Diffusion Coefficients DLS cannot measure D s. As an alternative, the tracer diffusion coefficient is measured for a ternary solution in which the second solute (matrix) is isorefractive with the solvent.

19 Mutual Diffusion Coefficients In a good solvent, A 2 M is sufficiently large to make k D positive. specific volume DLS measures D m in binary solutions: with backflow correction

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