| 36 |
used. |
used. |
| 37 |
|
|
| 38 |
The ocean model is coupled to the sea-ice model discussed in |
The ocean model is coupled to the sea-ice model discussed in |
| 39 |
Section~\ref{sec:model} with the following specific options. The |
Section~\ref{sec:model} using the following specific options. The |
| 40 |
zero-heat-capacity thermodynamics formulation of \citet{hib80} is used to |
zero-heat-capacity thermodynamics formulation of \citet{hib80} is used to |
| 41 |
compute sea ice thickness and concentration. Snow cover and sea ice salinity |
compute sea ice thickness and concentration. Snow cover and sea ice salinity |
| 42 |
are prognostic. |
are prognostic. Open water, dry ice, wet ice, dry snow, and wet snow albedo |
| 43 |
|
are, respectively, 0.15, 0.88, 0.79, 0.97, and 0.83. Ice mechanics follow the |
| 44 |
Ice mechanics follow the viscous plastic rheology of |
viscous plastic rheology of \citet{hibler79} and the ice momentum equation is |
| 45 |
\citet{hibler79} and the ice momentum equation is solved numerically using the |
solved numerically using the C-grid implementation of the \citet{zhang97} LSR |
| 46 |
C-grid implementation of the \citet{zha97} LSR dyanmics model discussed |
dynamics model discussed hereinabove. The ice is coupled to the ocean using |
| 47 |
hereinabove. |
the rescaled vertical coordinate system, z$^\ast$, of |
| 48 |
|
\citet{cam08}, that is, sea ice does not float above the ocean model but |
| 49 |
Open water, dry |
rather deforms the ocean's model surface level. |
| 50 |
ice, wet ice, dry snow, and wet snow albedo are, respectively, 0.15, 0.85, |
|
| 51 |
0.76, 0.94, and 0.8. |
This particular ECCO2 simulation is initialized from temperature and salinity |
| 52 |
|
fields derived from the Polar science center Hydrographic Climatology (PHC) |
| 53 |
\subsection{Arctic Domain with Open Boundaries} |
3.0 \citep{ste01a}. Surface boundary conditions for the period January 1979 to |
| 54 |
\label{sec:arctic} |
July 2002 are derived from the European Centre for Medium-Range Weather |
| 55 |
|
Forecasts (ECMWF) 40 year re-analysis (ERA-40) \citep{upp05}. Surface |
| 56 |
|
boundary conditions after September 2002 are derived from the ECMWF |
| 57 |
|
operational analysis. There is a one month transition period, August 2002, |
| 58 |
|
during which the ERA-40 contribution decreases linearly from 1 to 0 and the |
| 59 |
|
ECMWF analysis contribution increases linearly from 0 to 1. Six-hourly |
| 60 |
|
surface winds, temperature, humidity, downward short- and long-wave |
| 61 |
|
radiations, and precipitation are converted to heat, freshwater, and wind |
| 62 |
|
stress fluxes using the \citet{large81,large82} bulk formulae. Shortwave |
| 63 |
|
radiation decays exponentially as per \citet{pau77}. Low frequency |
| 64 |
|
precipitation has been adjusted using the pentad (5-day) data from the Global |
| 65 |
|
Precipitation Climatology Project (GPCP) \citep{huf01}. The time-mean river |
| 66 |
|
run-off from \citet{lar01} is applied globally, except in the Arctic Ocean |
| 67 |
|
where monthly mean river runoff based on the Arctic Runoff Data Base (ARDB) |
| 68 |
|
and prepared by P. Winsor (personnal communication, 2007) is specificied. |
| 69 |
|
Additionally, there is a relaxation to the monthly-mean climatological sea |
| 70 |
|
surface salinity values from PHC 3.0, a relaxation time scale of 101 days. |
| 71 |
|
|
| 72 |
|
Vertical mixing follows \citet{lar94} but with meridionally and vertically |
| 73 |
|
varying background vertical diffusivity; at the surface, vertical diffusivity |
| 74 |
|
is $4.4\times 10^{-6}$~m$^2$~s$^{-1}$ at the Equator, $3.6\times |
| 75 |
|
10^{-6}$~m$^2$~s$^{-1}$ north of 70$^\circ$N, and $1.9\times |
| 76 |
|
10^{-5}$~m$^2$~s$^{-1}$ south of 30$^\circ$S and between 30$^\circ$N and |
| 77 |
|
60$^\circ$N , with sinusoidally varying values in between these latitudes; |
| 78 |
|
vertically, diffusivity increases to $1.1\times 10^{-4}$~m$^2$~s$^{-1}$ at a a |
| 79 |
|
depth of 6150 m as per \citet{bry79}. A high order monotonicity-preserving |
| 80 |
|
advection scheme \citep{dar04} is employed and there is no explicit horizontal |
| 81 |
|
diffusivity. Horizontal viscosity follows \citet{lei96} but modified to sense |
| 82 |
|
the divergent flow as per \citet{kem08}. |
| 83 |
|
|
| 84 |
\subsection{Arctic Domain with Open Boundaries} |
\subsection{Arctic Domain with Open Boundaries} |
| 85 |
\label{sec:arctic} |
\label{sec:arctic} |
| 86 |
|
|
| 87 |
A second series of forward sensitivity experiments have been carried out on an |
A series of forward sensitivity experiments have been carried out on an |
| 88 |
Arctic Ocean domain with open boundaries. Once again the objective is to |
Arctic Ocean domain with open boundaries. The objective is to compare the old |
| 89 |
compare the old B-grid LSR dynamic solver with the new C-grid LSR and EVP |
B-grid LSR dynamic solver with the new C-grid LSR and EVP solvers. One |
| 90 |
solvers. One additional experiment is carried out to illustrate the |
additional experiment is carried out to illustrate the differences between the |
| 91 |
differences between the two main options for sea ice thermodynamics in the MITgcm. |
two main options for sea ice thermodynamics in the MITgcm. |
| 92 |
|
|
| 93 |
The Arctic domain of integration is illustrated in Fig.~\ref{fig:arctic1}. It |
The Arctic domain of integration is illustrated in Fig.~\ref{fig:arctic1}. It |
| 94 |
is carved out from, and obtains open boundary conditions from, the |
is carved out from, and obtains open boundary conditions from, the global |
| 95 |
global cubed-sphere configuration of the Estimating the Circulation |
cubed-sphere configuration described above. The horizontal domain size is |
| 96 |
and Climate of the Ocean, Phase II (ECCO2) project |
420 by 384 grid boxes. |
|
\citet{menemenlis05}. The domain size is 420 by 384 grid boxes |
|
|
horizontally with mean horizontal grid spacing of 18 km. |
|
| 97 |
|
|
| 98 |
\begin{figure} |
\begin{figure} |
| 99 |
%\centerline{{\includegraphics*[width=0.44\linewidth]{\fpath/arctic1.eps}}} |
%\centerline{{\includegraphics*[width=0.44\linewidth]{\fpath/arctic1}}} |
| 100 |
\caption{Bathymetry of Arctic Domain.\label{fig:arctic1}} |
\caption{Bathymetry of Arctic Domain.\label{fig:arctic1}} |
| 101 |
\end{figure} |
\end{figure} |
| 102 |
|
|
| 103 |
There are 50 vertical levels ranging in thickness from 10 m near the surface |
Difference from cube sphere is that it does not use z* coordinates nor |
| 104 |
to approximately 450 m at a maximum model depth of 6150 m. Bathymetry is from |
realfreshwater fluxes because it is not supported by open boundary code. |
|
the National Geophysical Data Center (NGDC) 2-minute gridded global relief |
|
|
data (ETOPO2) and the model employs the partial-cell formulation of |
|
|
\citet{adcroft97:_shaved_cells}, which permits accurate representation of the bathymetry. The |
|
|
model is integrated in a volume-conserving configuration using a finite volume |
|
|
discretization with C-grid staggering of the prognostic variables. In the |
|
|
ocean, the non-linear equation of state of \citet{jackett95}. The ocean model is |
|
|
coupled to a sea-ice model described hereinabove. |
|
|
|
|
|
This particular ECCO2 simulation is initialized from rest using the |
|
|
January temperature and salinity distribution from the World Ocean |
|
|
Atlas 2001 (WOA01) [Conkright et al., 2002] and it is integrated for |
|
|
32 years prior to the 1996--2001 period discussed in the study. Surface |
|
|
boundary conditions are from the National Centers for Environmental |
|
|
Prediction and the National Center for Atmospheric Research |
|
|
(NCEP/NCAR) atmospheric reanalysis [Kistler et al., 2001]. Six-hourly |
|
|
surface winds, temperature, humidity, downward short- and long-wave |
|
|
radiations, and precipitation are converted to heat, freshwater, and |
|
|
wind stress fluxes using the \citet{large81, large82} bulk formulae. |
|
|
Shortwave radiation decays exponentially as per Paulson and Simpson |
|
|
[1977]. Additionally the time-mean river run-off from Large and Nurser |
|
|
[2001] is applied and there is a relaxation to the monthly-mean |
|
|
climatological sea surface salinity values from WOA01 with a |
|
|
relaxation time scale of 3 months. Vertical mixing follows |
|
|
\citet{large94} with background vertical diffusivity of |
|
|
$1.5\times10^{-5}\text{\,m$^{2}$\,s$^{-1}$}$ and viscosity of |
|
|
$10^{-3}\text{\,m$^{2}$\,s$^{-1}$}$. A third order, direct-space-time |
|
|
advection scheme with flux limiter is employed \citep{hundsdorfer94} |
|
|
and there is no explicit horizontal diffusivity. Horizontal viscosity |
|
|
follows \citet{lei96} but |
|
|
modified to sense the divergent flow as per Fox-Kemper and Menemenlis |
|
|
[in press]. Shortwave radiation decays exponentially as per Paulson |
|
|
and Simpson [1977]. Additionally, the time-mean runoff of Large and |
|
|
Nurser [2001] is applied near the coastline and, where there is open |
|
|
water, there is a relaxation to monthly-mean WOA01 sea surface |
|
|
salinity with a time constant of 45 days. |
|
| 105 |
|
|
| 106 |
Open water, dry |
Open water, dry |
| 107 |
ice, wet ice, dry snow, and wet snow albedo are, respectively, 0.15, 0.85, |
ice, wet ice, dry snow, and wet snow albedo are, respectively, 0.15, 0.85, |
| 147 |
\item VP vs.\ EVP: speed performance, accuracy? |
\item VP vs.\ EVP: speed performance, accuracy? |
| 148 |
\item ocean stress: different water mass properties beneath the ice |
\item ocean stress: different water mass properties beneath the ice |
| 149 |
\end{itemize} |
\end{itemize} |
| 150 |
|
|
| 151 |
|
\begin{figure} |
| 152 |
|
\centerline{{\includegraphics*[width=0.6\linewidth]{\fpath/JFM1992uvice}}} |
| 153 |
|
\caption{Surface sea ice velocity for different solver flavors. |
| 154 |
|
\label{fig:iceveloc}} |
| 155 |
|
\end{figure} |
| 156 |
|
|
| 157 |
|
\begin{figure} |
| 158 |
|
\centerline{{\includegraphics*[width=0.6\linewidth]{\fpath/Jan1992xport}}} |
| 159 |
|
\caption{Transport through Canadian Archipelago for different solver flavors. |
| 160 |
|
\label{fig:archipelago}} |
| 161 |
|
\end{figure} |
| 162 |
|
|
| 163 |
|
\begin{figure} |
| 164 |
|
\centerline{{\includegraphics*[width=0.6\linewidth]{\fpath/JFM2000heff}}} |
| 165 |
|
\caption{Sea ice thickness for different solver flavors. |
| 166 |
|
\label{fig:icethick}} |
| 167 |
|
\end{figure} |
| 168 |
|
|
| 169 |
|
%%% Local Variables: |
| 170 |
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%%% mode: latex |
| 171 |
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%%% TeX-master: "ceaice" |
| 172 |
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%%% End: |
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