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\section{Introduction} |
This document provides the reader with the information necessary to |
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This documentation provides the reader with the information necessary to |
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carry out numerical experiments using MITgcm. It gives a comprehensive |
carry out numerical experiments using MITgcm. It gives a comprehensive |
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description of the continuous equations on which the model is based, the |
description of the continuous equations on which the model is based, the |
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numerical algorithms the model employs and a description of the associated |
numerical algorithms the model employs and a description of the associated |
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both process and general circulation studies of the atmosphere and ocean are |
both process and general circulation studies of the atmosphere and ocean are |
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also presented. |
also presented. |
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\section{Introduction} |
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MITgcm has a number of novel aspects: |
MITgcm has a number of novel aspects: |
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\begin{itemize} |
\begin{itemize} |
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\end{itemize} |
\end{itemize} |
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Key publications reporting on and charting the development of the model are |
Key publications reporting on and charting the development of the model are |
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listed in an Appendix. |
\cite{hill:95,marshall:97a,marshall:97b,adcroft:97,marshall:98,adcroft:99,hill:99,maro-eta:99}: |
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\begin{verbatim} |
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Hill, C. and J. Marshall, (1995) |
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Application of a Parallel Navier-Stokes Model to Ocean Circulation in |
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Parallel Computational Fluid Dynamics |
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In Proceedings of Parallel Computational Fluid Dynamics: Implementations |
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and Results Using Parallel Computers, 545-552. |
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Elsevier Science B.V.: New York |
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Marshall, J., C. Hill, L. Perelman, and A. Adcroft, (1997) |
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Hydrostatic, quasi-hydrostatic, and nonhydrostatic ocean modeling |
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J. Geophysical Res., 102(C3), 5733-5752. |
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Marshall, J., A. Adcroft, C. Hill, L. Perelman, and C. Heisey, (1997) |
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A finite-volume, incompressible Navier Stokes model for studies of the ocean |
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on parallel computers, |
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J. Geophysical Res., 102(C3), 5753-5766. |
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Adcroft, A.J., Hill, C.N. and J. Marshall, (1997) |
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Representation of topography by shaved cells in a height coordinate ocean |
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model |
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Mon Wea Rev, vol 125, 2293-2315 |
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Marshall, J., Jones, H. and C. Hill, (1998) |
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Efficient ocean modeling using non-hydrostatic algorithms |
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Journal of Marine Systems, 18, 115-134 |
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Adcroft, A., Hill C. and J. Marshall: (1999) |
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A new treatment of the Coriolis terms in C-grid models at both high and low |
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resolutions, |
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Mon. Wea. Rev. Vol 127, pages 1928-1936 |
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Hill, C, Adcroft,A., Jamous,D., and J. Marshall, (1999) |
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A Strategy for Terascale Climate Modeling. |
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In Proceedings of the Eighth ECMWF Workshop on the Use of Parallel Processors |
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in Meteorology, pages 406-425 |
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World Scientific Publishing Co: UK |
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Marotzke, J, Giering,R., Zhang, K.Q., Stammer,D., Hill,C., and T.Lee, (1999) |
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Construction of the adjoint MIT ocean general circulation model and |
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application to Atlantic heat transport variability |
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J. Geophysical Res., 104(C12), 29,529-29,547. |
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\end{verbatim} |
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We begin by briefly showing some of the results of the model in action to |
We begin by briefly showing some of the results of the model in action to |
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give a feel for the wide range of problems that can be addressed using it. |
give a feel for the wide range of problems that can be addressed using it. |
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the departure of the model from observations (both remotely sensed and |
the departure of the model from observations (both remotely sensed and |
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in-situ) over an interval of time, is minimized by adjusting `control |
in-situ) over an interval of time, is minimized by adjusting `control |
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parameters' such as air-sea fluxes, the wind field, the initial conditions |
parameters' such as air-sea fluxes, the wind field, the initial conditions |
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etc. Figure \ref{fig:assimilated-globes} shows an estimate of the time-mean |
etc. Figure \ref{fig:assimilated-globes} shows the large scale planetary |
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surface elevation of the ocean obtained by bringing the model in to |
circulation and a Hopf-Muller plot of Equatorial sea-surface height. |
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Both are obtained from assimilation bringing the model in to |
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consistency with altimetric and in-situ observations over the period |
consistency with altimetric and in-situ observations over the period |
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1992-1997. {\bf CHANGE THIS TEXT - FIG FROM PATRICK/CARL/DETLEF} |
1992-1997. |
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%% CNHbegin |
%% CNHbegin |
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\input{part1/globes_figure} |
\input{part1/assim_figure} |
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%% CNHend |
%% CNHend |
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\subsection{Ocean biogeochemical cycles} |
\subsection{Ocean biogeochemical cycles} |
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\subsection{Simulations of laboratory experiments} |
\subsection{Simulations of laboratory experiments} |
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Figure \ref{fig:lab-simulation} shows MITgcm being used to simulate a |
Figure \ref{fig:lab-simulation} shows MITgcm being used to simulate a |
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laboratory experiment inquiring in to the dynamics of the Antarctic Circumpolar Current (ACC). An |
laboratory experiment inquiring into the dynamics of the Antarctic Circumpolar Current (ACC). An |
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initially homogeneous tank of water ($1m$ in diameter) is driven from its |
initially homogeneous tank of water ($1m$ in diameter) is driven from its |
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free surface by a rotating heated disk. The combined action of mechanical |
free surface by a rotating heated disk. The combined action of mechanical |
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and thermal forcing creates a lens of fluid which becomes baroclinically |
and thermal forcing creates a lens of fluid which becomes baroclinically |
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and encoded. The model variables have different interpretations depending on |
and encoded. The model variables have different interpretations depending on |
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whether the atmosphere or ocean is being studied. Thus, for example, the |
whether the atmosphere or ocean is being studied. Thus, for example, the |
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vertical coordinate `$r$' is interpreted as pressure, $p$, if we are |
vertical coordinate `$r$' is interpreted as pressure, $p$, if we are |
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modeling the atmosphere (left hand side of figure \ref{fig:isomorphic-equations}) |
modeling the atmosphere (right hand side of figure \ref{fig:isomorphic-equations}) |
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and height, $z$, if we are modeling the ocean (right hand side of figure |
and height, $z$, if we are modeling the ocean (left hand side of figure |
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\ref{fig:isomorphic-equations}). |
\ref{fig:isomorphic-equations}). |
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%%CNHbegin |
%%CNHbegin |
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at fixed and moving $r$ surfaces we set (see figure \ref{fig:zandp-vert-coord}): |
at fixed and moving $r$ surfaces we set (see figure \ref{fig:zandp-vert-coord}): |
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\begin{equation} |
\begin{equation} |
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\dot{r}=0atr=R_{fixed}(x,y)\text{ (ocean bottom, top of the atmosphere)} |
\dot{r}=0 \text{\ at\ } r=R_{fixed}(x,y)\text{ (ocean bottom, top of the atmosphere)} |
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\label{eq:fixedbc} |
\label{eq:fixedbc} |
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\end{equation} |
\end{equation} |
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\begin{equation} |
\begin{equation} |
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\dot{r}=\frac{Dr}{Dt}atr=R_{moving}\text{ \ |
\dot{r}=\frac{Dr}{Dt} \text{\ at\ } r=R_{moving}\text{ \ |
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(ocean surface,bottom of the atmosphere)} \label{eq:movingbc} |
(ocean surface,bottom of the atmosphere)} \label{eq:movingbc} |
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\end{equation} |
\end{equation} |
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