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    Wang, Chen and Balmforth, Neil J. 2018. Strato-rotational instability without resonance. Journal of Fluid Mechanics, Vol. 846, Issue. , p. 815.
    Thomas, Jim Bühler, Oliver and Shafer Smith, K. 2018. Wave-induced mean flows in rotating shallow water with uniform potential vorticity. Journal of Fluid Mechanics, Vol. 839, Issue. , p. 408.
    van den Bremer, T. S. and Breivik, Ø. 2018. Stokes drift. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 376, Issue. 2111, p. 20170104.
    Read, P. L. 2018. A Chorus of the Winds-On Saturn!. Journal of Geophysical Research: Planets,
    Gilbert, Andrew D. and Vanneste, Jacques 2018. Geometric generalised Lagrangian-mean theories. Journal of Fluid Mechanics, Vol. 839, Issue. , p. 95.
    van den Bremer, T. S. and Sutherland, B. R. 2018. The wave-induced flow of internal gravity wavepackets with arbitrary aspect ratio. Journal of Fluid Mechanics, Vol. 834, Issue. , p. 385.
    Coutant, Antonin and Weinfurtner, Silke 2018. Low-frequency analogue Hawking radiation: The Korteweg–de Vries model. Physical Review D, Vol. 97, Issue. 2,
    Cotter, C. J. Gottwald, G. A. and Holms, D. D. 2017. Stochastic partial differential fluid equations as a diffusive limit of deterministic Lagrangian multi-time dynamics. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Science, Vol. 473, Issue. 2205, p. 20170388.
    Dunphy, Michael Ponte, Aurélien L. Klein, Patrice and Le Gentil, Sylvie 2017. Low-Mode Internal Tide Propagation in a Turbulent Eddy Field. Journal of Physical Oceanography, Vol. 47, Issue. 3, p. 649.
    Thomas, Jim 2017. New model for acoustic waves propagating through a vortical flow. Journal of Fluid Mechanics, Vol. 823, Issue. , p. 658.
    Cohen, Naftali Y. and Boos, William R. 2017. The influence of orographic Rossby and gravity waves on rainfall. Quarterly Journal of the Royal Meteorological Society, Vol. 143, Issue. 703, p. 845.
    Grooms, Ian 2017. Simulations of eddy kinetic energy transport in barotropic turbulence. Physical Review Fluids, Vol. 2, Issue. 11,
    Warneford, Emma S. and Dellar, Paul J. 2017. Super- and sub-rotating equatorial jets in shallow water models of Jovian atmospheres: Newtonian cooling versus Rayleigh friction. Journal of Fluid Mechanics, Vol. 822, Issue. , p. 484.
    Coutant, Antonin and Weinfurtner, Silke 2016. The imprint of the analogue Hawking effect in subcritical flows. Physical Review D, Vol. 94, Issue. 6,
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    Huang, Clare S. Y. and Nakamura, Noboru 2016. Local Finite-Amplitude Wave Activity as a Diagnostic of Anomalous Weather Events. Journal of the Atmospheric Sciences, Vol. 73, Issue. 1, p. 211.
    Nagura, Motoki and McPhaden, Michael J. 2016. Zonal Propagation of Near-Surface Zonal Currents in Relation to Surface Wind Forcing in the Equatorial Indian Ocean. Journal of Physical Oceanography, Vol. 46, Issue. 12, p. 3623.
    Cohen, Naftali Y. and Boos, William R. 2016. Modulation of subtropical stratospheric gravity waves by equatorial rainfall. Geophysical Research Letters, Vol. 43, Issue. 1, p. 466.
    Thomson, Stephen I. and McIntyre, Michael E. 2016. Jupiter’s Unearthly Jets: A New Turbulent Model Exhibiting Statistical Steadiness without Large-Scale Dissipation*. Journal of the Atmospheric Sciences, Vol. 73, Issue. 3, p. 1119.
    Cohen, Naftali Y. Gerber, Edwin P. and Bühler, Oliver 2014. What Drives the Brewer–Dobson Circulation?. Journal of the Atmospheric Sciences, Vol. 71, Issue. 10, p. 3837.
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    Waves and Mean Flows
    • Online ISBN: 9781107478701
    • Book DOI: https://doi.org/10.1017/CBO9781107478701
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Book description

Interactions between waves and mean flows play a crucial role in understanding the long-term aspects of atmospheric and oceanographic modelling. Indeed, our ability to predict climate change hinges on our ability to model waves accurately. This book gives a modern account of the nonlinear interactions between waves and mean flows, such as shear flows and vortices. A detailed account of the theory of linear dispersive waves in moving media is followed by a thorough introduction to classical wave-mean interaction theory. The author then extends the scope of the classical theory and lifts its restriction to zonally symmetric mean flows. It can be used as a fundamental reference, a course text, or by geophysicists and physicists needing a first introduction. This second edition includes brand new material, including a section on Langmuir circulations and the Craik–Leibovich instability. The author has also added exercises to aid students' learning.

Reviews

Review of the first edition:‘Its approach is systematic, building surely and steadily from the simplest examples to the most far-reaching generalizations, and it should therefore suit graduate students and mature researchers alike. And on top of that, it's fun to read! The style is witty and occasionally quirky, but adds up to an almost miraculous combination of succinctness and explicitness.'

M. E. Young Source: Journal of Fluid Mechanics

Review of the first edition:‘Bühler's well-organized textbook is excellent in all the most important ways. The author is well known in the field for applications of the GLM formulation to real-world problems, and his book will likely become the authoritative resource on the subject. Waves and Mean Flows presents its readers with a clearly written text that is comfortable to read. As a logically laid-out, internally consistent, and self-contained work, it will be useful both as a textbook and as a handy reference for researchers.'

Steve K. Lamoreaux Source: Physics Today

Review of the first edition:‘For anyone wishing to work seriously with the GLM approach, Waves and Mean Flows is indispensable.'

Source: Physics Today

Review of the first edition:‘… this text is, to my knowledge, the best existing source for a comprehensive introduction to the GLM theory. Many important concepts, such as the development of Lagrangian-mean divergence in divergence-free Eulerian flows, are explained with clarity, often through the use of elegant examples … Its intentionally provocative deviation from habitual Eulerian-mean thinking is certain to prove valuable and stimulating, and will no doubt have the desired long-term mean effect of raising the scientific community's conceptual center of gravity in this important field of inquiry.'

Source: Bulletin of the American Meteorological Society

Review of the first edition:‘The book is written in a very unpretentious, direct style. This book is an excellent investment for atmospheric and oceanic dynamicists and many environmental and mechanical engineers. Applied mathematicians who want to understand geophysical waves deeply and/or ray tracing will like this book, too.'

Source: SIAM Review

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Contents
References
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