18 |
\begin{itemize} |
\begin{itemize} |
19 |
\item it can be used to study both atmospheric and oceanic phenomena; one |
\item it can be used to study both atmospheric and oceanic phenomena; one |
20 |
hydrodynamical kernel is used to drive forward both atmospheric and oceanic |
hydrodynamical kernel is used to drive forward both atmospheric and oceanic |
21 |
models - see fig.1% |
models - see fig.1 |
22 |
\marginpar{ |
\marginpar{ |
23 |
Fig.1 One model}\ref{fig:onemodel} |
Fig.1 One model}\ref{fig:onemodel} |
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\item it has a non-hydrostatic capability and so can be used to study both |
\item it has a non-hydrostatic capability and so can be used to study both |
26 |
small-scale and large scale processes - see fig.2% |
small-scale and large scale processes - see fig.2 |
27 |
\marginpar{ |
\marginpar{ |
28 |
Fig.2 All scales}\ref{fig:all-scales} |
Fig.2 All scales}\ref{fig:all-scales} |
29 |
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30 |
\item finite volume techniques are employed yielding an intuitive |
\item finite volume techniques are employed yielding an intuitive |
31 |
discretization and support for the treatment of irregular geometries using |
discretization and support for the treatment of irregular geometries using |
32 |
orthogonal curvilinear grids and shaved cells - see fig.3% |
orthogonal curvilinear grids and shaved cells - see fig.3 |
33 |
\marginpar{ |
\marginpar{ |
34 |
Fig.3 Finite volumes}\ref{fig:Finite volumes} |
Fig.3 Finite volumes}\ref{fig:Finite volumes} |
35 |
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