C. Snyder et A. Joly, DEVELOPMENT OF PERTURBATIONS WITHIN GROWING BAROCLINIC WAVES, Quarterly Journal of the Royal Meteorological Society, 124(550), 1998, pp. 1961-1983
We explore the linear stability of a growing, three-dimensional barocl
inic wave by calculating the perturbation that grows most rapidly over
various time intervals and at Various stages in the development of th
e parent wave and its fronts. Three norms are used to measure growth:
volume-integrated energy, enstrophy and stream function variance. The
flow is assumed adiabatic and quasi-geostrophic for simplicity, and pe
rturbations are required to have uniform potential vorticity. These ra
pidly growing perturbations can produce realistic sub-structures withi
n the parent wave, such as upper-level vorticity maxima that propagate
relative to a synoptic-scale parent wave or packets of synoptic-scale
waves within a planetary-wave basic state. For a synoptic-scale paren
t wave and the energy or enstrophy norms, however, the dominant charac
teristic of the fastest growing perturbations is that they rapidly evo
lve toward a final structure corresponding to a phase shift and slight
change of shape of the original wave-in essence, the initial perturba
tion modifies the parent wave and the jet on which it propagates, whic
h results in a modification, which grows in time, of the phase and amp
litude of the parent wave. Amplifications in energy or enstrophy are a
lso small compared to what would be estimated based on the locally lar
ge shears and baroclinicity within the parent wave. The fronts appear
to be stabilized by the combined influences of synoptic-scale horizont
al deformation and the natural movement of perturbations relative to t
he parent wave.