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Atmospheric Science 4320 / 7320

Atmospheric Science 4320 / 7320. Anthony R. Lupo. Day one. Let’s talk about fundamental Kinematic Concepts In lab, we talked about divergence, which is a scalar quantity:. Day one. We can prove that divergence is the fractional change with time of some horizontal area A. Day one/two. Then

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Atmospheric Science 4320 / 7320

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  1. Atmospheric Science 4320 / 7320 Anthony R. Lupo

  2. Day one • Let’s talk about fundamental Kinematic Concepts • In lab, we talked about divergence, which is a scalar quantity:

  3. Day one • We can prove that divergence is the fractional change with time of some horizontal area A.

  4. Day one/two • Then • finally:

  5. Day two • We could extend the concept to 3-D and get:

  6. Day two • Horizontal divergence in terms of a line integral, invoking Green’s theorem (2-D) and Gauss’ (3-D) theorem • Define area A (with tangential wind vectors)

  7. Day two • We must also assume Green’s theorem holds defining a line integral:

  8. Day two • Green’s theorem (where P = u and Q = v) • S is the oriented surface, or the position vector on the curve is R • thus ds = dr • F is a vector field in the normal direction on S, in our case V (which is tangent to the curve) where we consider:

  9. Day two • So F is: The normal component is:

  10. Day two • And we invoke Green’s theorem; • Now recall vector identity: Ax(BxC) = (AdotC)B - C(AdotB)

  11. Day two • And see that: • And what is the second term on the RHS equal to????

  12. Day two • In 3-D we invoke Gauss’s theorem: • Stoke’s Theorem

  13. Day two • Recall Green’s theorem: • And,

  14. Day two • Then

  15. Day two • And;

  16. Day two • And if you don’t understand this: • You might have a ….little …trouble…

  17. Day two • Horizontal divergence in Natural Coordinates: • (s,n,z,t) • The Velocity in Natural Components: • and,

  18. Day two • so, the horizontal divergence is: • aha, product rule! (which terms will drop out as 0?

  19. Day two • Recall: • And;

  20. Day two • Sooo, • A B

  21. Day two • In the Above relationship • Term A refers to the speed divergence: • Term B is the directional divergence (Diffluence)

  22. Day two • Speed Div

  23. Day two • Diffluence (directional div)

  24. Day two • In a typical synoptic situation, these terms tend to act opposite each other: • Confluence and speed increasing: • Diffluence and speed decreasing:

  25. Day two • Alternative derivation of horizontal divergence in natural coordinates: • Then take derivative (product rule again:

  26. Day two/three • If we “rotate” i and j (x and y) to coincide with s and n (s and n) then: • Thus,

  27. Day two/three • and, • Then, the celebrated result!

  28. Day three • We can also perform our simple-minded area analysis along the same lines:

  29. Day three • Then • finally:

  30. Day three • Divergence in the Large-Scale Meteorological Coordinate System: • The divergence refers to the cartesian coordinate which is an invariant coordinate. • On large-scales we need to take into account the curvature of the earth’s surface.

  31. Day three • However, the earth is curved, thus all else being equal, if we move a large airmass (approximated as 2 - D)northward (southward), the area gets smaller (larger) implying convergence (divergence). • We can consider the parcel moving upward or downward also (the area or volume):

  32. Day three • These discrepencies arise from the fact that the Earth is a sphere, and thus we cannot hold i, j, and k constant. • Recall we re-worked the Navier - Stokes equations to be valid on a spherical surface:

  33. Day three • The equation

  34. Day three • We can also define divergence: • Thus, for example (can you do the rest?)

  35. Day three • then; • Recall, we defined expressions for:

  36. Day three • thus, we get, for the divergence:

  37. Day three • How important are these “correction terms” for each scale?

  38. Day three • And; Then (this approximation is fine too!),

  39. Day three • Orders of magnitude of Horizontal divergence and vertical motions:

  40. Day three/four • Vorticity and Circulation/ unit area • Vorticity is a vector whose magnitude is directly proportional to the circulation/unit area of a plane normal to the vorticity vector. • Vorticity = Curl(V), ROT(V), or

  41. Day four • We are primarily interested in the vertical component of vorticity due to circulations in the horizontal plane: • (xi) (eta) (zeta)

  42. Day four • The vertical component: • This is called relative vorticity:

  43. Day four • Circulation (Kelvin’s Theorem): • consider a closed curve S, and by definition: • or • R = the position vector • dr = change in the position vector

  44. Day four • from Green’s Theorem: • then:

  45. Day four • Thus, circulation per unit area: • We need to show that: • Recall, line integral definition:

  46. Day four • Then,

  47. Day four • And theeen,

  48. Day four • So,

  49. Day four • Thus, we get the vertical component of Vorticity: • Let’s Examine the vorticity on a sphere: • Vorticity:

  50. Day four • Look at using ‘foil’, u-comp only:

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