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Non-particulate 2-phase systems.

Non-particulate 2-phase systems. (See Roe Sects 5.3, 1.6) Remember: I( q ) = ∫   ( r ) exp(-i qr ) d r In this form, integral does not converge. So deviation from the mean <n> =  ( r ) =  ( r ) - <n>. Non-particulate 2-phase systems. (See Roe Sects 5.3, 1.6) Remember:

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Non-particulate 2-phase systems.

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  1. Non-particulate 2-phase systems. (See Roe Sects 5.3, 1.6) Remember: I(q) = ∫(r)exp(-iqr) dr In this form, integral does not converge. So deviation from the mean <n> = (r) = (r) - <n>

  2. Non-particulate 2-phase systems. (See Roe Sects 5.3, 1.6) Remember: I(q) = (r)exp(-iqr) dr In this form, integral does not converge. So deviation from the mean <> = (r) = (r) - <> Then (r) =∫(u) (u + r) du (r) =∫((u) + <>) ((u + r) + <>) du

  3. Non-particulate 2-phase systems. deviation from the mean <> = (r) = (r) - <> Then (r) =∫(u) (u + r) du (r) =∫((u) + <>) ((u + r) + <>) du (r) =∫(u) (u + r) du + <>2∫du + <>∫(u) du + <>∫(u + r) du

  4. Non-particulate 2-phase systems. deviation from the mean <> = (r) = (r) - <> Then (r) =∫(u) (u + r) du (r) =∫((u) + <>) ((u + r) + <>) du (r) =∫(u) (u + r) du + <>2∫du + <>∫(u) du + <>∫(u + r) du 0 0

  5. Non-particulate 2-phase systems. deviation from the mean <> = (r) = (r) - <> Then (r) =∫(u) (u + r) du (r) =∫((u) + <>) ((u + r) + <>) du (r) =∫(u) (u + r) du + <>2∫du + <>∫(u) du + <>∫(u + r) du (r) = (r) + <>2V 0 0 volume of specimen

  6. Non-particulate 2-phase systems. deviation from the mean <> = (r) = (r) - <> Then (r) =∫(u) (u + r) du (r) =∫((u) + <>) ((u + r) + <>) du (r) =∫(u) (u + r) du + <>2∫du + <>∫(u) du + <>∫(u + r) du (r) = (r) + <>2V 0 0 leads to null scattering

  7. Non-particulate 2-phase systems. (r) = (r) Finally I(q) = ∫(r)exp(-iqr) dr Normalization of (r): (r) = (r)/ (0) where (0) =∫(u) (u + 0) du = <2>V Then: I(q) = <2>V∫(r)exp(-iqr) dr

  8. Non-particulate 2-phase systems. I(q) = <2>V∫(r)exp(-iqr) dr Remember the invariant (total scattering power of specimen): Q =∫I(S) dS = (1/(2π)3)∫I(q) dq = total scattering over the whole of reciprocal space For isotropic material: Q = 4∫S2 I(S) dS= (1/(2π2))∫q2 I(q) dq (S = (2 sin )/ = q/2) ∞ ∞ o o

  9. Non-particulate 2-phase systems. For isotropic material: Q = 4∫S2 I(S) dS= (1/(2π2))∫q2 I(q) dq Q = ∫(r) [(1/(2π2))∫exp(-iqr) dq ]dr = (0) = <2>V ∞ ∞ o o

  10. Non-particulate 2-phase systems. Now for the model - Ideal 2-phase system: only 2 regions or phases each phase has constant scattering length density sharp phase boundary randomly mixed isotropic

  11. Non-particulate 2-phase systems. Now for the model - Ideal 2-phase system: only 2 regions or phases each phase has constant scattering length density sharp phase boundary randomly mixed isotropic Can get: volume fractionsi of each phase & interface area

  12. 1 1 <> 2 2 Non-particulate 2-phase systems. Ideal 2-phase system: <> = 1122 1 = 1 - <> = 2 2 = 2 - <> = 1  = 1 - 2 = 1 + 2

  13. 1 1 <> 2 2 Non-particulate 2-phase systems. Ideal 2-phase system: <> = 1122 1 = 1 - <> = 2 2 = 2 - <> = 1  = 1 - 2 = 1 + 2 Q = <2>V = V (12 if 1, 2known, Q --> 1, 2 if 1, 2 known, Q --> 1 - 2

  14. Non-particulate 2-phase systems. Ideal 2-phase system: Most important result - Porod law: I(q) --> (2()2 S)/q4 at large q S = total boundary area betwn 2 phases log I(q) = const – 4 x log q

  15. Non-particulate 2-phase systems. Ideal 2-phase system: Most important result - Porod law: I(q) --> (2()2 S)/q4 at large q S = total boundary area betwn 2 phases log I(q) = const – 4 x log q

  16. Non-particulate 2-phase systems. Ideal 2-phase system: Most important result - Porod law: I(q) --> (2()2 S)/q4 at large q S = total boundary area betwn 2 phases log I(q) = const – 4 x log q Need absolute Is If relative Is, can get invariant Q --> S/V I(q)/Q = (2S)/(12Vq4)

  17. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Ideal 2-phase system: only 2 regions or phases each phase has constant scattering length density sharp phase boundary randomly mixed isotropic

  18. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Ideal 2-phase system: only 2 regions or phases each phase has constant scattering length density sharp phase boundary randomly mixed isotropic Density fluctuations (from thermal motion): I(q) = Io(q) + I1(q) + I2(q) + I12(q) uniform density density fluctuations interaction betwn phases

  19. Non-particulate 2-phase systems. Deviations from ideal 2-phase system I(q) = Io(q) + I1(q) + I2(q) + I12(q) uniform density density fluctuations interaction betwn phases = intensity from pure phases short range correlations - weighted by vol %s small, neglected

  20. Non-particulate 2-phase systems. Deviations from ideal 2-phase system I(q) = Io(q) + I1(q) + I2(q) + I12(q) uniform density density fluctuations interaction betwn phases = intensity from pure phases short range correlations - weighted by vol %s small, neglected To correct, then, measure scattering from the 2 pure phases

  21. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Al otro lado: can make empirical correction for I1(q) + I2(q) intensity high angle region q

  22. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Diffuse boundary betwn phase regions: let (r) = scattering length density in 2-phase matl w/ diffuse boundaries id(r) = scattering length density in the same 2-phase matl w/ sharp boundaries (hypothetical)

  23. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Diffuse boundary betwn phase regions: let (r) = scattering length density in 2-phase matl w/ diffuse boundaries id(r) = scattering length density in the same 2-phase matl w/ sharp boundaries (hypothetical) Then (r)=id(r) * g(r) g(r) = fcn which characterizes diffuse boundaries

  24. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Diffuse boundary betwn phase regions: let (r) = scattering length density in 2-phase matl w/ diffuse boundaries id(r) = scattering length density in the same 2-phase matl w/ sharp boundaries (hypothetical) Then (r)=id(r) * g(r) g(r) = fcn which characterizes diffuse boundaries I(q) = Iid(q) G2(q) G(q) = Fourier transform of g(r) (Fourier transform of convolution of 2 fcns = product of their transforms)

  25. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Diffuse boundary betwn phase regions: (r)=id(r) * g(r) g(r) = fcn which characterizes diffuse boundaries I(q) = Iid(q) G2(q) G(q) = Fourier transform of g(r) (Fourier transform of convolution of 2 fcns = product of their transforms) Common: G(q) = exp(–2/2)q2 & for small bdy width (): I(q) = Iid(q) (1 - 2 q2)

  26. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Diffuse boundary betwn phase regions: I(q) = Iid(q) (1 - 2 q2) q4 I(q) = (2()2 S) - (2()2 S) (2 q2) q4 I(q) q2

  27. Non-particulate 2-phase systems. Deviations from ideal 2-phase system Diffuse boundary betwn phase regions:

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