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METO 621

METO 621. Lesson 11. Azimuthal Dependence.

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METO 621

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  1. METO 621 Lesson 11

  2. Azimuthal Dependence • In slab geometry, the flux and mean intensity depend only on t and m. If we need to solve for the intensity or source function, then we need to solve for t, m and f. However it is possible to reduce the latter problem to two variables by introducing a mathematical transformation.

  3. Azimuthal Dependence • The first moment of the phase function is commonly denoted by the symbol g=c1. • This represents the degree of assymetry of the angular scattering and is called the assymetry factor. Special values of g are • When g=0 - isotropic scattering • When g=-1 - complete backscattering • When g=+1- complete forward scattering

  4. Legendre Polynomials • The Legendre polynomials comprise a natural basis set of orthogonal polynomials over the domain • The first five Legendre polynomials are • P0(u)=1 P1(u)=u P2(u)=1/2.(3u2-1) • P3(u)=1/2.(5u3-3u) P4(u)=1/8.(35u4-30u2+3) • Legendre polynomials are orthogonal

  5. Azimuthal Dependence • We can now expand the phase function • Inverting the order of summation we get

  6. Azimuthal Dependence • This expansion of the phase function is essentially a Fourier cosine series, and hence we should be able to expand the intensity in a similar fashion. • We can now write a radiative transfer equation for each component

  7. Azimuthal Dependence

  8. Examples of Phase Functions • Rayleigh Phase Function. If we assume that the molecule is isotropic, and the incident radiation is unpolarized then the normalised phase function is:

  9. Rayleigh Phase Function • The azimuthally averaged phase function is • In terms of Legendre polynomials

  10. Rayleigh Phase Function • The assymetry factor is therefore

  11. Mie-Debye Phase Function

  12. Mie-Debye Phase Function • Scattering of solar radiation by large particles is characterized by forward scattering with a diffraction peak in the forward direction • Mie-Debye theory - mathematical formulation is complete. Numerical implementation is challenging • Scaling transformations

  13. Scaling Transformations

  14. Scaling Transformations • The examples shown of the phase function versus the scattering angle all show a strong forward peak. If we were to plot the phase function versus the cosine of the scattering angle - the unit actually used in radiative transfer- then the forward peak becomes more pronounced. • Approaches a delta function • Can treat the forward peak as an unscattered beam, and add it to the solar flux term.

  15. Scaling Transformations • Then the remainder of the phase function is expanded in Legendre Polynomials. • This is known as the d-N approximation • There are simpler approximations

  16. The d-Isotropic Approximation • The crudest form is to assume that, outside of the forward peak, the remainder of the phase function is a constant, Basically this assumes isotropic scattering outside of the peak. The azimuthally averaged phase function becomes • When this phase function is substituted into the azimuthally averaged radiative transfer equation we get:

  17. The d-Isotropic Approximation

  18. The d-Isotropic Approximation

  19. The d-Two-Term Approximation • A better approximation results by representing the remainder of the phase function by two terms (setting N=1 in the full expansion). We now get:

  20. The d-Two-Term Approximation • Substituting into the azimuthally averaged radiative transfer equation:

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