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Quasi-stationary atmospheric responses to large-scale forcingKang, In-sik 27 March 1984 (has links)
A time-dependent, spectral, barotropic model and a similar
two-layer primitive equation model are developed to investigate the
planetary-scale wave responses to various types of large-scale
forcing: vorticity and heat sources, and sea surface temperature (SST)
anomalies. Both models are linearized about the zonal mean states of
January climatology.
The characteristics of forced Rossby waves are extensively studied
based on both the barotropic model experiments and the theory of Rossby
wave propagation on the sphere (Hoskins and Karoly, 1981). In particular,
both model and theoretical results show that the responses are
dominated by ultra-long wave components (zonal wavenumber m = 1, 2, and
3), and that the large responses occur for vorticity sources located at
the subtropics and at the high latitudes near 45°N. The model experiments
for the wavenumber-dependent sources located at various latitudes
show that the ultra-long waves behave like a north-south seesaw between
the high and middle latitudes (m = 1) or between the high latitudes and
subtropics (m = 2). The north-south seesaw of zonal wavenumber 1
component is in good agreement with that observed by Gambo and Kudo
(1983). The responses of long waves (m > 3) are, however, localized in
the source regions with relatively small amplitudes.
The characteristics of baroclinic responses to prescribed heat
sources located at various latitudes are also examined. Over the
source latitudes baroclinic responses are dominant; however, the remote
responses have a barotropic structure. The north-south seesaws appearing
in the barotropic model are also observed in the baroclinic model.
A series of baroclinic model experiments, in which surface heat
fluxes and internal heating are computed in terms of the model variables,
are also conducted to investigate the linear effect of
sea-surface temperature (SST) anomalies on the atmospheric circulation.
The experiments for prescribed SST anomalies, taken equal to twice
those of Rasmusson and Carpenter (1982), simulate many aspects of the
associated observed atmospheric anomalies, and suggest, therefore, that
a large part of the atmosphere's responses occur via linear dynamics.
It is also suggested that the rather weak responses in the North
Pacific are due to the lack of a zonally varying basic state. In the
case where the SST anomalies are located in the middle latitudes, the
responses are about five times smaller than for the tropical SST
anomalies. This result is also fairly consistent with the GCM experimental
results by Chervin et al. (1976).
Subsequent experiments, using climatological January SSTs in the
tropics, suggest that the tropical Pacific SST can be an important
factor in maintaining the climatological standing waves, at least over
the western half of the Northern Hemisphere. / Graduation date: 1984
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Linear and nonlinear Rossby waves in basins both with and without a thin meridional barrier /Atherton, Juli. January 1900 (has links)
Thesis (S.M.)--Joint Program in Physical Oceanography at the Massachusetts Institute of Technology and the Woods Hole Oceanographic Institution, 2002. / Includes bibliographical references (p. 119).
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Linearized stationary planetary wave modelling with tropospheric forcingJones, Richard Edward. January 1980 (has links)
No description available.
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Numerical simulation of critical layer evolutionRitchie, C. Harold (Charles Harold) January 1978 (has links)
No description available.
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Vertical resolution effects in a steady long wave modelToth, Garry, 1951- January 1978 (has links)
No description available.
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A barotropic stability study of free and forced planetary waves /Fyfe, John January 1987 (has links)
The stability of free and forced planetary waves in a $ beta$-channel is investigated with a barotropic model. The forced waves at equilibrium result from a constant mean-zonal wind interacting with a finite-amplitude topography. / The frequencies of all infinitesimal perturbations to the equilibrium flows are determined numerically as a function of the flow parameters. The results are interpreted using a truncated spectral model and related to those of previous studies with infinite $ beta$-planes. In contrast to some earlier analytical studies we find that unstable long waves $(L sb{x}$ $>$ $L sb{y})$ exist under superresonant conditions. We also report on the existence of an interesting travelling topographic instability. / The linear instability of a weakly non-zonal flow is investigated numerically and analytically (via WKB theory). The theory reproduces the qualitative nature of the numerically-determined fastest-growing mode. / Nonlinear integrations, involving many degrees of freedom, reveal that initially-infinitesimal disturbances may grow explosively to finite-amplitude. The longer-term integrations are interpreted using a statistical mechanical model.
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Numerical study of the nonlinear Rossby wave critical level development in a barotropic zonal flowBéland, Michel January 1977 (has links)
No description available.
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Normal mode global Rossby waves theory and observations /Ahlquist, Jon Elling. January 1981 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1981. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 86-92).
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Linearized stationary planetary wave modelling with tropospheric forcingJones, Richard Edward. January 1980 (has links)
No description available.
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Numerical simulation of critical layer evolutionRitchie, C. Harold (Charles Harold) January 1978 (has links)
No description available.
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