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Rossby%20Waves

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The Rossby wave analysis in Holton's Chapter 7 is set in a simple, ... m2 0 evanescent wave (not propagating) And. So for a stationary wave (c=0) we have... – PowerPoint PPT presentation

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Title: Rossby%20Waves


1
Rossby Waves
  • Prof. Alison Bridger
  • MET 205A
  • October, 2007

2
Review
  • The Rossby wave analysis in Holtons Chapter 7 is
    set in a simple, barotropic atmosphere.
  • We are able show that the waves exist, and that
    they propagate westward.
  • In a slightly more complicated analysis these
    waves can be shown to propagate north-south, as
    well as east-west.
  • Karoly and Hoskins (1982) looked at Rossby wave
    propagation in a spherical barotropic model, and
    showed that from a source region, waves propagate
    away following a great circle.

3
Continued...
  • By this mechanism, disturbances can be spread to
    remote regions of Earth (e.g., from the tropics
    to mid-latitudes, for example as a consequence of
    El Nino).
  • These simple Rossby waves do not propagate in the
    vertical.

4
Rossby Waves in a Stratified Atmosphere
  • In a stratified atmosphere, the BVE is no longer
    the appropriate equation to study.
  • Instead we must use the QGPVE (Cht 6).
  • The analysis can get a lot more complicated!
  • As usual, we linearize the QGPVE to study waves,
    and we assume a non-zero background wind U.
  • If Uconstant, we can solve analytically.
  • If not, we cannot!!!

5
continued...
  • With Uconstant, we get (Holton 12.11)
  • where
  • And ?? is the eddy streamfunction.

6
continued...
  • To solve, we assume the usual
  • The quantity ?(z) is the amplitude, and in this
    case can be a function of height. Substitution
    shows that ?(z) satisfies this 2nd order ODE

7
continued...
  • In solving this, we find the vertical propagation
    characteristics (just like with internal gravity
    waves)
  • m2 gt 0 ? propagation
  • m2 lt 0 ? evanescent wave (not propagating)
  • And

8
  • So for a stationary wave (c0) we have
  • Rossby waves can propagate in this case provided
    the prevailing background wind has these
    properties
  • FIRST, The prevailing background wind U must be
    positive!
  • This means that Rossby waves will only propagate
    upward (e.g., from tropospheric sources into the
    stratosphere) when the background winds are
    positive (westerly), as they are in winter.
  • This explains why in winter (U gt 0) we observe
    large-scale waves in the stratosphere, whereas in
    summer (U lt 0) they are absent!

9
  • Here, we are talking about stationary planetary
    waves, rather than travelling waves.
  • SECOND, the westerly winds cannot be too strong,
    and the critical strength depends on the scale of
    the wave.
  • The scale-dependence is such that wave one can
    most effectively propagate upward, wave two
    somewhat less effectively, wave three even less,
    etc.

10
continued...
  • This explains why we see large-amplitudes in
    waves one and two in the stratosphere, but much
    smaller amplitudes in waves three and upward.
  • A NEXT STEP is to let U be linear in z.
  • At this point (already!) the resulting equation
    (the vertical structure equation) becomes
    difficult to solve.
  • This analysis was first performed by Charney
    Drazin (1961) a paper that is often referred
    to!

11
continued...
  • If you then proceed to assume U(y,z) as is more
    realistic you leave the realm of being able to
    solve the exact equation on paper. Instead we
    solve computationally.
  • When U(y,z), we can develop a second order PDE
    for the (complex) wave amplitude, ?(y,z), having
    assumed a solution of the usual wave-like form.

12
continued...
  • The governing equation is then
  • Here, and
  • is the basic state potential vorticity
    refer back to Eq. 6.25.

13
continued...
  • depends upon U and its first and
    second order derivatives in the vertical and in
    the horizontal.
  • The quantity n2 is the equivalent of a
    (refractive index) 2 - just as in the
    propagation of light!
  • Thus, Rossby waves will tend to propagate into
    regions of high n2, and will avoid regions of
    negative n2.

14
continued...
  • Plots of n2 - when compared with plots of wave
    amplitude (both as functions of y and z) - help
    us understand the distribution of wave amplitude.
  • We note that n2 depends also on wavenumber
    squared.
  • The impact of this is that if wave one can
    propagate for a certain wind structure, wave two
    may not be able to (etc. for waves three, etc.)

15
continued...
  • This is a generalization of the result above for
    constant U (and again explains why we see waves
    one and two in the stratosphere, but not so much
    three onward).
  • The first numerical solution of the problem is
    due to Matsuno (1970), who solved the structure
    equation on a hemispheric yz-grid.
  • He assumed a background wind state UU(y,z) that
    was analytical, but a fair representation of
    observed wintertime stratospheric winds.

16
continued...
  • He solved for the steady wave structure
    (amplitude and phase as functions of y and z for
    waves one and two).
  • The forcing was provided via specification of
    wave amplitude at the lower boundary - simulating
    the upward propagation of wave energy from the
    troposphere.
  • Matsuno also computed the (refractive index) 2
    quantity, thus demonstrating the link between
    (refractive index) 2 and wave amplitude
    distribution.

17
continued...
  • The results compared well with observations in a
    general sense (meaning that they might not look
    like a specific winter, but might generally look
    like observations).
  • Subsequent work has looked at
  • how variations in wind profiles (sometimes
    subtle) impact wave structures
  • the role of different forcing mechanisms
    (topographic vs thermal)
  • solution of the full primitive equation problem
    (Matsuno solved the QG version)
  • detailed calculations of travelling Rossby modes
    with realistic background states

18
continued...
  • for example, there is a 5-day wave both observed
    and theoretically predicted
  • it has these characteristics wave one
    (east-west), symmetric about the equator,
    westward propagating with a period of 5 days
  • the simulated wave has the same characteristics
    and these do not depend strongly upon the
    background wind details
  • there are other modes that are very sensitive to
    the background winds
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