Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by
Crossref.
1983.
The response of finite-amplitude wave motions to seasonal heating of a baroclinic shear flow.
Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences,
Vol. 387,
Issue. 1793,
p.
257.
Moroz, I. M.
and
Brindley, J.
1984.
Nonlinear Amplitude Evolution of Baroclinic Wave Trains and Wave Packets.
Studies in Applied Mathematics,
Vol. 70,
Issue. 1,
p.
21.
Wakata, Y.
and
Uryu, M.
1984.
Non-Linear Behaviors of Forced Baroclinic Wave in a Continuous Zonal Flow.
Journal of the Meteorological Society of Japan. Ser. II,
Vol. 62,
Issue. 6,
p.
809.
Yoshida, Atsushi
and
Hart, John E.
1986.
A numerical study of baroclinic chaos.
Geophysical & Astrophysical Fluid Dynamics,
Vol. 37,
Issue. 1-2,
p.
1.
Pedlosky, Joseph
1987.
Geophysical Fluid Dynamics.
p.
490.
Appleby, J. C.
1988.
Selection of baroclinic waves.
Quarterly Journal of the Royal Meteorological Society,
Vol. 114,
Issue. 482,
p.
1173.
Klein, Patrice
1990.
Transition to chaos in unstable baroclinic systems: a review.
Fluid Dynamics Research,
Vol. 5,
Issue. 4,
p.
235.
Gimson, Neil R.
Brindley, John
and
Moroz, Irene M.
1991.
Amplitude vacillation of baroclinic waves in a rotating fluid system.
Geophysical & Astrophysical Fluid Dynamics,
Vol. 59,
Issue. 1-4,
p.
25.
Allen, J. S.
Samelson, R. M.
and
Newberger, P. A.
1991.
Chaos in a model of forced quasi-geostrophic flow over topography: an application of Melnikov's method.
Journal of Fluid Mechanics,
Vol. 226,
Issue. ,
p.
511.
Lu, Huei-Iin
Miller, Timothy L.
and
Butler, Karen A.
1994.
A numerical study of wavenumber selection in the baroclinic annulus flow system.
Geophysical & Astrophysical Fluid Dynamics,
Vol. 75,
Issue. 1,
p.
1.
Holford, Joanne M.
and
Dalziel, Stuart B.
1996.
Measurements of layer depth during baroclinic instability in a two-layer flow.
Applied Scientific Research,
Vol. 56,
Issue. 2-3,
p.
191.
Früh, W. -G.
and
Read, P. L.
1997.
Wave interactions and the transition to chaos of baroclinic waves in a thermally driven rotating annulus.
Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences,
Vol. 355,
Issue. 1722,
p.
101.
Grotjahn, Richard
Hodyss, Daniel
and
Immel, Sheri
2003.
A technique for creating linearly stable localized atmospheric features with an application to nonlinear cyclogenesis.
Dynamics of Atmospheres and Oceans,
Vol. 37,
Issue. 1,
p.
25.
Mitchell, D. A.
Teague, W. J.
Wimbush, M.
Watts, D. R.
and
Sutyrin, G. G.
2005.
The Dok Cold Eddy.
Journal of Physical Oceanography,
Vol. 35,
Issue. 3,
p.
273.
Wolfe, Christopher L.
and
Samelson, Roger M.
2006.
Normal-Mode Analysis of a Baroclinic Wave-Mean Oscillation.
Journal of the Atmospheric Sciences,
Vol. 63,
Issue. 11,
p.
2795.
WILLIAMS, PAUL D.
READ, PETER L.
and
HAINE, THOMAS W. N.
2010.
Testing the limits of quasi-geostrophic theory: application to observed laboratory flows outside the quasi-geostrophic regime.
Journal of Fluid Mechanics,
Vol. 649,
Issue. ,
p.
187.
Tulloch, Ross
Marshall, John
Hill, Chris
and
Smith, K. Shafer
2011.
Scales, Growth Rates, and Spectral Fluxes of Baroclinic Instability in the Ocean.
Journal of Physical Oceanography,
Vol. 41,
Issue. 6,
p.
1057.
O’Gorman, Paul A.
2011.
The Effective Static Stability Experienced by Eddies in a Moist Atmosphere.
Journal of the Atmospheric Sciences,
Vol. 68,
Issue. 1,
p.
75.
Pieri, A. B.
Cambon, C.
Godeferd, F. S.
and
Salhi, A.
2012.
Linearized potential vorticity mode and its role in transition to baroclinic instability.
Physics of Fluids,
Vol. 24,
Issue. 7,
Früh, Wolf‐Gerrit
2014.
Modeling Atmospheric and Oceanic Flows.
p.
61.