lmd_all1990.bib
@comment{{This file has been generated by bib2bib 1.98}}
@comment{{Command line: /usr/bin/bib2bib --quiet -c 'not journal:"Discussions"' -c 'not journal:"Polymer Science"' -c year=1990 -c $type="ARTICLE" -oc lmd_all1990.txt -ob lmd_all1990.bib ./EMC3all.link.bib}}
@article{1990JAtS...47.2475G,
author = {{Genthon}, C. and {Le Treut}, H. and {Sadourny}, R. and {Jouzel}, J.
},
title = {{Parameterization of eddy sensible heat transports in a zonally averaged dynamic model of the atmosphere.}},
journal = {Journal of Atmospheric Sciences},
keywords = {Earth Atmosphere: Dynamics, Earth Atmosphere: Models},
year = 1990,
month = nov,
volume = 47,
pages = {2475-2487},
abstract = {{A Charney-Branscome based parameterization has been tested as a way of
representing the eddy sensible heat transports missing in a zonally
averaged dynamic model (ZADM) of the atmosphere. The ZADM used is a
zonally averaged version of a General Circulation Model (GCM). The
parameterized transports in the ZADM are gaged against the corresponding
fluxes explicitly simulated in the GCM, using the same zonally averaged
boundary conditions in both models. The Charney-Branscome approach
neglects stationary eddies and transient barotropic disturbances and
relies on a set of simplifying assumptions, including the linear
approximation, to describe growing transient baroclinic eddies.
Nevertheless, fairly satisfactory results are obtained when the
parameterization is performed interactively with the model. Compared
with noninteractive tests, a very efficient restoring feedback effect
between the modeled zonal-mean climate and the parameterized meridional
eddy transport is identified.
}},
doi = {10.1175/1520-0469(1990)047<2475:POESHT>2.0.CO;2},
adsurl = {http://adsabs.harvard.edu/abs/1990JAtS...47.2475G},
adsnote = {Provided by the SAO/NASA Astrophysics Data System}
}
@article{1990JGR....9516601C,
author = {{Cess}, R.~D. and {Potter}, G.~L. and {Blanchet}, J.~P. and
{Boer}, G.~J. and {Del Genio}, A.~D. and {DéQué}, M. and
{Dymnikov}, V. and {Galin}, V. and {Gates}, W.~L. and {Ghan}, S.~J. and
{Kiehl}, J.~T. and {Lacis}, A.~A. and {Le Treut}, H. and {Li}, Z.-X. and
{Liang}, X.-Z. and {McAvaney}, B.~J. and {Meleshko}, V.~P. and
{Mitchell}, J.~F.~B. and {Morcrette}, J.-J. and {Randall}, D.~A. and
{Rikus}, L. and {Roeckner}, E. and {Royer}, J.~F. and {Schlese}, U. and
{Sheinin}, D.~A. and {Slingo}, A. and {Sokolov}, A.~P. and {Taylor}, K.~E. and
{Washington}, W.~M. and {Wetherald}, R.~T. and {Yagai}, I. and
{Zhang}, M.-H.},
title = {{Intercomparison and interpretation of climate feedback processes in 19 atmospheric general circulation models}},
journal = {\jgr},
keywords = {Meteorology and Atmospheric Dynamics: Climatology, Meteorology and Atmospheric Dynamics: General circulation},
year = 1990,
month = sep,
volume = 95,
pages = {16601},
abstract = {{The need to understand differences among general circulation model
projections of CO$_{2}$-induced climatic change has motivated the
present study, which provides an intercomparison and interpretation of
climate feedback processes in 19 atmospheric general circulation models.
This intercomparison uses sea surface temperature change as a surrogate
for climate change. The interpretation of cloud-climate interactions is
given special attention. A roughly threefold variation in one measure of
global climate sensitivity is found among the 19 models. The important
conclusion is that most of this variation is attributable to differences
in the models' depiction of cloud feedback, a result that emphasizes the
need for improvements in the treatment of clouds in these models if they
are ultimately to be used as reliable climate predictors. It is further
emphasized that cloud feedback is the consequence of all interacting
physical and dynamical processes in a general circulation model. The
result of these processes is to produce changes in temperature, moisture
distribution, and clouds which are integrated into the radiative
response termed cloud feedback.
}},
doi = {10.1029/JD095iD10p16601},
adsurl = {http://adsabs.harvard.edu/abs/1990JGR....9516601C},
adsnote = {Provided by the SAO/NASA Astrophysics Data System}
}
@article{1990JCli....3..865P,
author = {{Picon}, L. and {Desbois}, M.},
title = {{Relation between METEOSAT Water Vapor Radiance Fields and Large Scale Tropical Circulation Features.}},
journal = {Journal of Climate},
year = 1990,
month = aug,
volume = 3,
pages = {865-876},
abstract = {{Mean monthly images from the water vapor channel of METEOSAT
characteristically contain large-scale spatial structures, especially in
tropical regions. The aim of this paper is to establish connections
between these structures and large-scale circulation features. For this
purpose, statistical relationships between radiances and some
meteorological parameters provided by ECMWF analyses are
studied.Temporal correlations are computed for two sizes of regions, in
order to compare temporal changes associated with both large-scale
circulations and smaller scale systems. The correlations obtained are
poor, suggesting that the chosen parameters are not well related at
short time scales.Temporal averages appear more suitable for these
comparisons. As expected, the mean relative humidity yields the best
correlation with the mean water vapor radiances. A (weaker) relationship
exists also with mean dynamic fields: large water vapor radiances are
almost always related to subsidence in the middle troposphere,
divergence near the surface, and convergence in the upper troposphere.
However, there is regional variability in the results., one explanation
may be different contributions from horizontal advecion and vertical
motions to the humidity of the middle troposphere.
}},
doi = {10.1175/1520-0442(1990)003<0865:RBMWVR>2.0.CO;2},
adsurl = {http://adsabs.harvard.edu/abs/1990JCli....3..865P},
adsnote = {Provided by the SAO/NASA Astrophysics Data System}
}
@article{1990JFM...214..535B,
author = {{Babiano}, A. and {Basdevant}, C. and {Le Roy}, P. and {Sadourny}, R.
},
title = {{Relative dispersion in two-dimensional turbulence}},
journal = {Journal of Fluid Mechanics},
keywords = {Computational Fluid Dynamics, Incompressible Flow, Turbulence Effects, Two Dimensional Flow, Asymptotic Properties, Differential Equations, Energy Spectra, Velocity Distribution},
year = 1990,
month = may,
volume = 214,
pages = {535-557},
abstract = {{The statistical laws governing relative dispersion of particle pairs
advected in a two-dimensional turbulent, incompressible, homogeneous,
and stationary velocity field are examined theoretically and
numerically. A rigorous differential equation governing relative
dispersion is obtained which is based on simple kinematic relations
between relative position, relative velocity, and relative acceleration
of particle views and is valid for both two- and three-dimensional
dynamics. Particular attention is given to the classical Kraichnan-Lin
and Richardson-Obukhov laws in the incompressible two-dimensional case.
}},
doi = {10.1017/S0022112090000258},
adsurl = {http://adsabs.harvard.edu/abs/1990JFM...214..535B},
adsnote = {Provided by the SAO/NASA Astrophysics Data System}
}
