articles/ceaice/ceaice_model.tex

\section{Model}
\label{sec:model}

\subsection{Dynamics}
\label{sec:dynamics}

The momentum equation of the sea-ice model is
\begin{equation}
  \label{eq:momseaice}
  m \frac{D\vek{u}}{Dt} = -mf\vek{k}\times\vek{u} + \vtau_{air} +
  \vtau_{ocean} - m \nabla{\phi(0)} + \vek{F},
\end{equation}
where $m=m_{i}+m_{s}$ is the ice and snow mass per unit area;
$\vek{u}=u\vek{i}+v\vek{j}$ is the ice velocity vector;
$\vek{i}$, $\vek{j}$, and $\vek{k}$ are unit vectors in the $x$, $y$, and $z$
directions, respectively;
$f$ is the Coriolis parameter;
$\vtau_{air}$ and $\vtau_{ocean}$ are the wind-ice and ocean-ice stresses,
respectively;
$g$ is the gravity accelation;
$\nabla\phi(0)$ is the gradient (or tilt) of the sea surface height;
$\phi(0) = g\eta + p_{a}/\rho_{0}$ is the sea surface height potential
in response to ocean dynamics ($g\eta$) and to atmospheric pressure
loading ($p_{a}/\rho_{0}$, where $\rho_{0}$ is a reference density);
and $\vek{F}=\nabla\cdot\sigma$ is the divergence of the internal ice stress
tensor $\sigma_{ij}$.
When using the rescaled vertical coordinate system, z$^\ast$, of
\citet{cam08}, $\phi(0)$ also includes a term due to snow and ice
loading, $mg/\rho_{0}$. 
Advection of sea-ice momentum is neglected. The wind and ice-ocean stress
terms are given by
\begin{align*}
  \vtau_{air}   = & \rho_{air}  C_{air}   |\vek{U}_{air}  -\vek{u}|
                   R_{air}  (\vek{U}_{air}  -\vek{u}), \\ 
  \vtau_{ocean} = & \rho_{ocean}C_{ocean} |\vek{U}_{ocean}-\vek{u}| 
                   R_{ocean}(\vek{U}_{ocean}-\vek{u}), \\ 
\end{align*}
where $\vek{U}_{air/ocean}$ are the surface winds of the atmosphere
and surface currents of the ocean, respectively; $C_{air/ocean}$ are
air and ocean drag coefficients; $\rho_{air/ocean}$ are reference
densities; and $R_{air/ocean}$ are rotation matrices that act on the
wind/current vectors.

For an isotropic system the stress tensor $\sigma_{ij}$ ($i,j=1,2$) can
be related to the ice strain rate and strength by a nonlinear
viscous-plastic (VP) constitutive law \citep{hibler79, zhang98}:
\begin{equation}
  \label{eq:vpequation}
  \sigma_{ij}=2\eta(\dot{\epsilon}_{ij},P)\dot{\epsilon}_{ij} 
  + \left[\zeta(\dot{\epsilon}_{ij},P) -
    \eta(\dot{\epsilon}_{ij},P)\right]\dot{\epsilon}_{kk}\delta_{ij}  
  - \frac{P}{2}\delta_{ij}.
\end{equation}
The ice strain rate is given by
\begin{equation*}
  \dot{\epsilon}_{ij} = \frac{1}{2}\left( 
    \frac{\partial{u_{i}}}{\partial{x_{j}}} +
    \frac{\partial{u_{j}}}{\partial{x_{i}}}\right).
\end{equation*}
The maximum ice pressure $P_{\max}$, a measure of ice strength, depends on
both thickness $h$ and compactness (concentration) $c$:
\begin{equation}
  P_{\max} = P^{*}c\,h\,e^{[C^{*}\cdot(1-c)]},
\label{eq:icestrength}
\end{equation}
with the constants $P^{*}$ and $C^{*}$. The nonlinear bulk and shear
viscosities $\eta$ and $\zeta$ are functions of ice strain rate
invariants and ice strength such that the principal components of the
stress lie on an elliptical yield curve with the ratio of major to
minor axis $e$ equal to $2$; they are given by:
\begin{align*}
  \zeta =& \min\left(\frac{P_{\max}}{2\max(\Delta,\Delta_{\min})},
   \zeta_{\max}\right) \\
  \eta =& \frac{\zeta}{e^2} \\
  \intertext{with the abbreviation}
  \Delta = & \left[
    \left(\dot{\epsilon}_{11}^2+\dot{\epsilon}_{22}^2\right)
    (1+e^{-2}) +  4e^{-2}\dot{\epsilon}_{12}^2 + 
    2\dot{\epsilon}_{11}\dot{\epsilon}_{22} (1-e^{-2})
  \right]^{-\frac{1}{2}}
\end{align*}
The bulk viscosities are bounded above by imposing both a minimum
$\Delta_{\min}=10^{-11}\text{\,s}^{-1}$ (for numerical reasons) and a
maximum $\zeta_{\max} = P_{\max}/\Delta^*$, where
$\Delta^*=(5\times10^{12}/2\times10^4)\text{\,s}^{-1}$. For stress
tensor computation the replacement pressure $P = 2\,\Delta\zeta$
\citep{hibler95} is used so that the stress state always lies on the
elliptic yield curve by definition.

In the so-called truncated ellipse method the shear viscosity $\eta$
is capped to suppress any tensile stress \citep{hibler97, geiger98}:
\begin{equation}
  \label{eq:etatem}
  \eta = \min\left(\frac{\zeta}{e^2},
  \frac{\frac{P}{2}-\zeta(\dot{\epsilon}_{11}+\dot{\epsilon}_{22})}
  {\sqrt{(\dot{\epsilon}_{11}+\dot{\epsilon}_{22})^2
      +4\dot{\epsilon}_{12}^2}}\right).
\end{equation}

In the current implementation, the VP-model is integrated with the
semi-implicit line successive over relaxation (LSOR)-solver of
\citet{zhang98}, which allows for long time steps that, in our case,
are limited by the explicit treatment of the Coriolis term. The
explicit treatment of the Coriolis term does not represent a severe
limitation because it restricts the time step to approximately the
same length as in the ocean model where the Coriolis term is also
treated explicitly.

\citet{hunke97}'s introduced an elastic contribution to the strain
rate in order to regularize Eq.\refeq{vpequation} in such a way that
the resulting elastic-viscous-plastic (EVP) and VP models are
identical at steady state,
\begin{equation}
  \label{eq:evpequation}
  \frac{1}{E}\frac{\partial\sigma_{ij}}{\partial{t}} +
  \frac{1}{2\eta}\sigma_{ij} 
  + \frac{\eta - \zeta}{4\zeta\eta}\sigma_{kk}\delta_{ij}  
  + \frac{P}{4\zeta}\delta_{ij}
  = \dot{\epsilon}_{ij}. 
\end{equation}
%In the EVP model, equations for the components of the stress tensor
%$\sigma_{ij}$ are solved explicitly. Both model formulations will be
%used and compared the present sea-ice model study.
The EVP-model uses an explicit time stepping scheme with a short
timestep. According to the recommendation of \citet{hunke97}, the
EVP-model is stepped forward in time 120 times within the physical
ocean model time step (although this parameter is under debate), to
allow for elastic waves to disappear.  Because the scheme does not
require a matrix inversion it is fast in spite of the small timestep
\citep{hunke97}. For completeness, we repeat the equations for the
components of the stress tensor $\sigma_{1} =
\sigma_{11}+\sigma_{22}$, $\sigma_{2}= \sigma_{11}-\sigma_{22}$, and
$\sigma_{12}$. Introducing the divergence $D_D =
\dot{\epsilon}_{11}+\dot{\epsilon}_{22}$, and the horizontal tension
and shearing strain rates, $D_T =
\dot{\epsilon}_{11}-\dot{\epsilon}_{22}$ and $D_S =
2\dot{\epsilon}_{12}$, respectively, and using the above abbreviations,
the equations can be written as:
\begin{align}
  \label{eq:evpstresstensor1}
  \frac{\partial\sigma_{1}}{\partial{t}} + \frac{\sigma_{1}}{2T} +
  \frac{P}{2T} &= \frac{P}{2T\Delta} D_D \\
  \label{eq:evpstresstensor2}
  \frac{\partial\sigma_{2}}{\partial{t}} + \frac{\sigma_{2} e^{2}}{2T}
  &= \frac{P}{2T\Delta} D_T \\
  \label{eq:evpstresstensor12}
  \frac{\partial\sigma_{12}}{\partial{t}} + \frac{\sigma_{12} e^{2}}{2T}
  &= \frac{P}{4T\Delta} D_S 
\end{align}
Here, the elastic parameter $E$ is redefined in terms of a damping timescale
$T$ for elastic waves \[E=\frac{\zeta}{T}.\]
$T=E_{0}\Delta{t}$ with the tunable parameter $E_0<1$ and
the external (long) timestep $\Delta{t}$. \citet{hunke97} recommend
$E_{0} = \frac{1}{3}$.

For details of the spatial discretization, the reader is referred to
\citet{zhang98, zhang03}. Our discretization differs only (but
importantly) in the underlying grid, namely the Arakawa C-grid, but is
otherwise straightforward. The EVP model, in particular, is discretized
naturally on the C-grid with $\sigma_{1}$ and $\sigma_{2}$ on the
center points and $\sigma_{12}$ on the corner (or vorticity) points of
the grid. With this choice all derivatives are discretized as central
differences and averaging is only involved in computing $\Delta$ and
$P$ at vorticity points.

For a general curvilinear grid, one needs in principle to take metric
terms into account that arise in the transformation of a curvilinear
grid on the sphere. For now, however, we can neglect these metric
terms because they are very small on the \ml{[modify following
  section3:] cubed sphere grids used in this paper; in particular,
only near the edges of the cubed sphere grid, we expect them to be
non-zero, but these edges are at approximately 35\degS\ or 35\degN\ 
which are never covered by sea-ice in our simulations.  Everywhere
else the coordinate system is locally nearly cartesian.}  However, for
last-glacial-maximum or snowball-earth-like simulations the question
of metric terms needs to be reconsidered.  Either, one includes these
terms as in \citet{zhang03}, or one finds a vector-invariant
formulation for the sea-ice internal stress term that does not require
any metric terms, as it is done in the ocean dynamics of the MITgcm
\citep{adcroft04:_cubed_sphere}.

Lateral boundary conditions are naturally ``no-slip'' for B-grids, as
the tangential velocities points lie on the boundary. For C-grids, the
lateral boundary condition for tangential velocities is realized via
``ghost points'', allowing alternatively no-slip or free-slip
conditions. In ocean models free-slip boundary conditions in
conjunction with piecewise-constant (``castellated'') coastlines have
been shown to reduce in effect to no-slip boundary conditions
\citep{adcroft98:_slippery_coast}; for sea-ice models the effects of
lateral boundary conditions have not yet been studied.

Moving sea ice exerts a stress on the ocean which is the opposite of
the stress $\vtau_{ocean}$ in Eq.\refeq{momseaice}. This stess is
applied directly to the surface layer of the ocean model. An
alternative ocean stress formulation is given by \citet{hibler87}.
Rather than applying $\vtau_{ocean}$ directly, the stress is derived
from integrating over the ice thickness to the bottom of the oceanic
surface layer. In the resulting equation for the \emph{combined}
ocean-ice momentum, the interfacial stress cancels and the total
stress appears as the sum of windstress and divergence of internal ice
stresses: $\delta(z) (\vtau_{air} + \vek{F})/\rho_0$, \citep[see also
Eq.\,2 of][]{hibler87}. The disadvantage of this formulation is that
now the velocity in the surface layer of the ocean that is used to
advect tracers, is really an average over the ocean surface
velocity and the ice velocity leading to an inconsistency as the ice
temperature and salinity are different from the oceanic variables.

Sea ice distributions are characterized by sharp gradients and edges.
For this reason, we employ positive, multidimensional 2nd and 3rd-order
advection scheme with flux limiter \citep{roe85, hundsdorfer94} for the
thermodynamic variables discussed in the next section.

\subparagraph{boundary conditions: no-slip, free-slip, half-slip}

\begin{itemize}
\item transition from existing B-Grid to C-Grid
\item boundary conditions: no-slip, free-slip, half-slip
\item fancy (multi dimensional) advection schemes
\item VP vs.\ EVP \citep{hunke97}
\item ocean stress formulation \citep{hibler87}
\end{itemize}

\subsection{Thermodynamics}
\label{sec:thermodynamics}

In the original formulation the sea ice model \citep{menemenlis05}
uses simple thermodynamics following the appendix of
\citet{semtner76}. This formulation does not allow storage of heat
(heat capacity of ice is zero, and this type of model is often refered
to as a ``zero-layer'' model). Upward conductive heat flux is parameterized
assuming a linear temperature profile and together with a constant ice
conductivity. It is expressed as $(K/h)(T_{w}-T_{0})$, where $K$ is
the ice conductivity, $h$ the ice thickness, and $T_{w}-T_{0}$ the
difference between water and ice surface temperatures. The surface
heat flux is computed in a similar way to that of \citet{parkinson79}
and \citet{manabe79}.

The conductive heat flux depends strongly on the ice thickness $h$.
However, the ice thickness in the model represents a mean over a
potentially very heterogeneous thickness distribution.  In order to
parameterize this sub-grid scale distribution for heat flux
computations, the mean ice thickness $h$ is split into seven thickness
categories $H_{n}$ that are equally distributed between $2h$ and
minimum imposed ice thickness of $5\text{\,cm}$ by $H_n=
\frac{2n-1}{7}\,h$ for $n\in[1,7]$. The heat flux for all thickness
categories is averaged to give the total heat flux.

The atmospheric heat flux is balanced by an oceanic heat flux from
below.  The oceanic flux is proportional to
$\rho\,c_{p}\left(T_{w}-T_{fr}\right)$ where $\rho$ and $c_{p}$ are
the density and heat capacity of sea water and $T_{fr}$ is the local
freezing point temperature that is a function of salinity. Contrary to
\citet{menemenlis05}, this flux is not assumed to instantaneously melt
or create ice, but a time scale of three days is used to relax $T_{w}$
to the freezing point.

The parameterization of lateral and vertical growth of sea ice follows
that of \citet{hibler79, hibler80}.

On top of the ice there is a layer of snow that modifies the heat flux
and the albedo \citep{zhang98}. If enough snow accumulates so that its
weight submerges the ice and the snow is flooded, a simple mass
conserving parameterization of snowice formation (a flood-freeze
algorithm following Archimedes' principle) turns snow into ice until
the ice surface is back at $z=0$ \citep{leppaeranta83}.

Effective ich thickness (ice volume per unit area,
$c\cdot{h}$), concentration $c$ and effective snow thickness
($c\cdot{h}_{snow}$) are advected by ice velocities as described in
\refsec{dynamics}. From the various advection scheme that are
available in the MITgcm \citep{mitgcm02}, we choose flux-limited
schemes to preserve sharp gradients and edges and to rule out
unphysical over- and undershoots (negative thickness or
concentration). These scheme conserve volume and horizontal area.
\ml{[do we need to proove that? can we proove that? citation?]}

There is considerable doubt about the reliability of such a simple
thermodynamic model---\citet{semtner84} found significant errors in
phase (one month lead) and amplitude ($\approx$50\%\,overestimate) in
such models---, so that today many sea ice models employ more complex
thermodynamics. A popular thermodynamics model of \citet{winton00} is
based on the 3-layer model of \citet{semtner76} and treats brine
content by means of enthalphy conservation. This model requires in
addition to ice-thickness and compactness (fractional area) additional
state variables to be advected by ice velocities, namely enthalphy of
the two ice layers and the thickness of the overlying snow layer.
\ml{[Jean-Michel, your turf: ]Care must be taken in advecting these
  quantities in order to ensure conservation of enthalphy. Currently
  this can only be accomplished with a 2nd-order advection scheme with
  flux limiter \citep{roe85}.}


\subsection{C-grid}
\begin{itemize}
\item no-slip vs. free-slip for both lsr and evp; 
  "diagnostics" to look at and use for comparison
  \begin{itemize}
  \item ice transport through Fram Strait/Denmark Strait/Davis
    Strait/Bering strait (these are general) 
  \item ice transport through narrow passages, e.g.\ Nares-Strait
  \end{itemize}
\item compare different advection schemes (if lsr turns out to be more
  effective, then with lsr otherwise I prefer evp), eg. 
  \begin{itemize}
  \item default 2nd-order with diff1=0.002
  \item 1st-order upwind with diff1=0.
  \item DST3FL (SEAICEadvScheme=33 with diff1=0., should work, works for me)
  \item 2nd-order wit flux limiter (SEAICEadvScheme=77 with diff1=0.)
  \end{itemize}
  That should be enough. Here, total ice mass and location of ice edge
  is interesting. However, this comparison can be done in an idealized
  domain, may not require full Arctic Domain?
\item
Do a little study on the parameters of LSR and EVP
\begin{enumerate}
\item convergence of LSR, how many iterations do you need to get a
  true elliptic yield curve 
\item vary deltaTevp and the relaxation parameter for EVP and see when
  the EVP solution breaks down (relative to the forcing time scale).
  For this, it is essential that the evp solver gives use "stripeless"
  solutions, that is your dtevp = 1sec solutions/or 10sec solutions
  with SEAICE\_evpDampC = 615.
\end{enumerate}

\end{itemize}

%%% Local Variables: 
%%% mode: latex
%%% TeX-master: "ceaice"
%%% End: 
1	\section{Model}
2	\label{sec:model}
3
4	\subsection{Dynamics}
5	\label{sec:dynamics}
6
7	The momentum equation of the sea-ice model is
8	\begin{equation}
9	\label{eq:momseaice}
10	m \frac{D\vek{u}}{Dt} = -mf\vek{k}\times\vek{u} + \vtau_{air} +
11	\vtau_{ocean} - m \nabla{\phi(0)} + \vek{F},
12	\end{equation}
13	where $m=m_{i}+m_{s}$ is the ice and snow mass per unit area;
14	$\vek{u}=u\vek{i}+v\vek{j}$ is the ice velocity vector;
15	$\vek{i}$, $\vek{j}$, and $\vek{k}$ are unit vectors in the $x$, $y$, and $z$
16	directions, respectively;
17	$f$ is the Coriolis parameter;
18	$\vtau_{air}$ and $\vtau_{ocean}$ are the wind-ice and ocean-ice stresses,
19	respectively;
20	$g$ is the gravity accelation;
21	$\nabla\phi(0)$ is the gradient (or tilt) of the sea surface height;
22	$\phi(0) = g\eta + p_{a}/\rho_{0}$ is the sea surface height potential
23	in response to ocean dynamics ($g\eta$) and to atmospheric pressure
24	loading ($p_{a}/\rho_{0}$, where $\rho_{0}$ is a reference density);
25	and $\vek{F}=\nabla\cdot\sigma$ is the divergence of the internal ice stress
26	tensor $\sigma_{ij}$.
27	When using the rescaled vertical coordinate system, z$^\ast$, of
28	\citet{cam08}, $\phi(0)$ also includes a term due to snow and ice
29	loading, $mg/\rho_{0}$.
30	Advection of sea-ice momentum is neglected. The wind and ice-ocean stress
31	terms are given by
32	\begin{align*}
33	\vtau_{air} = & \rho_{air} C_{air} \|\vek{U}_{air} -\vek{u}\|
34	R_{air} (\vek{U}_{air} -\vek{u}), \\
35	\vtau_{ocean} = & \rho_{ocean}C_{ocean} \|\vek{U}_{ocean}-\vek{u}\|
36	R_{ocean}(\vek{U}_{ocean}-\vek{u}), \\
37	\end{align*}
38	where $\vek{U}_{air/ocean}$ are the surface winds of the atmosphere
39	and surface currents of the ocean, respectively; $C_{air/ocean}$ are
40	air and ocean drag coefficients; $\rho_{air/ocean}$ are reference
41	densities; and $R_{air/ocean}$ are rotation matrices that act on the
42	wind/current vectors.
43
44	For an isotropic system the stress tensor $\sigma_{ij}$ ($i,j=1,2$) can
45	be related to the ice strain rate and strength by a nonlinear
46	viscous-plastic (VP) constitutive law \citep{hibler79, zhang98}:
47	\begin{equation}
48	\label{eq:vpequation}
49	\sigma_{ij}=2\eta(\dot{\epsilon}_{ij},P)\dot{\epsilon}_{ij}
50	+ \left[\zeta(\dot{\epsilon}_{ij},P) -
51	\eta(\dot{\epsilon}_{ij},P)\right]\dot{\epsilon}_{kk}\delta_{ij}
52	- \frac{P}{2}\delta_{ij}.
53	\end{equation}
54	The ice strain rate is given by
55	\begin{equation*}
56	\dot{\epsilon}_{ij} = \frac{1}{2}\left(
57	\frac{\partial{u_{i}}}{\partial{x_{j}}} +
58	\frac{\partial{u_{j}}}{\partial{x_{i}}}\right).
59	\end{equation*}
60	The maximum ice pressure $P_{\max}$, a measure of ice strength, depends on
61	both thickness $h$ and compactness (concentration) $c$:
62	\begin{equation}
63	P_{\max} = P^{}c\,h\,e^{[C^{}\cdot(1-c)]},
64	\label{eq:icestrength}
65	\end{equation}
66	with the constants $P^{}$ and $C^{}$. The nonlinear bulk and shear
67	viscosities $\eta$ and $\zeta$ are functions of ice strain rate
68	invariants and ice strength such that the principal components of the
69	stress lie on an elliptical yield curve with the ratio of major to
70	minor axis $e$ equal to $2$; they are given by:
71	\begin{align*}
72	\zeta =& \min\left(\frac{P_{\max}}{2\max(\Delta,\Delta_{\min})},
73	\zeta_{\max}\right) \\
74	\eta =& \frac{\zeta}{e^2} \\
75	\intertext{with the abbreviation}
76	\Delta = & \left[
77	\left(\dot{\epsilon}_{11}^2+\dot{\epsilon}_{22}^2\right)
78	(1+e^{-2}) + 4e^{-2}\dot{\epsilon}_{12}^2 +
79	2\dot{\epsilon}_{11}\dot{\epsilon}_{22} (1-e^{-2})
80	\right]^{-\frac{1}{2}}
81	\end{align*}
82	The bulk viscosities are bounded above by imposing both a minimum
83	$\Delta_{\min}=10^{-11}\text{\,s}^{-1}$ (for numerical reasons) and a
84	maximum $\zeta_{\max} = P_{\max}/\Delta^*$, where
85	$\Delta^*=(5\times10^{12}/2\times10^4)\text{\,s}^{-1}$. For stress
86	tensor computation the replacement pressure $P = 2\,\Delta\zeta$
87	\citep{hibler95} is used so that the stress state always lies on the
88	elliptic yield curve by definition.
89
90	In the so-called truncated ellipse method the shear viscosity $\eta$
91	is capped to suppress any tensile stress \citep{hibler97, geiger98}:
92	\begin{equation}
93	\label{eq:etatem}
94	\eta = \min\left(\frac{\zeta}{e^2},
95	\frac{\frac{P}{2}-\zeta(\dot{\epsilon}_{11}+\dot{\epsilon}_{22})}
96	{\sqrt{(\dot{\epsilon}_{11}+\dot{\epsilon}_{22})^2
97	+4\dot{\epsilon}_{12}^2}}\right).
98	\end{equation}
99
100	In the current implementation, the VP-model is integrated with the
101	semi-implicit line successive over relaxation (LSOR)-solver of
102	\citet{zhang98}, which allows for long time steps that, in our case,
103	are limited by the explicit treatment of the Coriolis term. The
104	explicit treatment of the Coriolis term does not represent a severe
105	limitation because it restricts the time step to approximately the
106	same length as in the ocean model where the Coriolis term is also
107	treated explicitly.
108
109	\citet{hunke97}'s introduced an elastic contribution to the strain
110	rate in order to regularize Eq.\refeq{vpequation} in such a way that
111	the resulting elastic-viscous-plastic (EVP) and VP models are
112	identical at steady state,
113	\begin{equation}
114	\label{eq:evpequation}
115	\frac{1}{E}\frac{\partial\sigma_{ij}}{\partial{t}} +
116	\frac{1}{2\eta}\sigma_{ij}
117	+ \frac{\eta - \zeta}{4\zeta\eta}\sigma_{kk}\delta_{ij}
118	+ \frac{P}{4\zeta}\delta_{ij}
119	= \dot{\epsilon}_{ij}.
120	\end{equation}
121	%In the EVP model, equations for the components of the stress tensor
122	%$\sigma_{ij}$ are solved explicitly. Both model formulations will be
123	%used and compared the present sea-ice model study.
124	The EVP-model uses an explicit time stepping scheme with a short
125	timestep. According to the recommendation of \citet{hunke97}, the
126	EVP-model is stepped forward in time 120 times within the physical
127	ocean model time step (although this parameter is under debate), to
128	allow for elastic waves to disappear. Because the scheme does not
129	require a matrix inversion it is fast in spite of the small timestep
130	\citep{hunke97}. For completeness, we repeat the equations for the
131	components of the stress tensor $\sigma_{1} =
132	\sigma_{11}+\sigma_{22}$, $\sigma_{2}= \sigma_{11}-\sigma_{22}$, and
133	$\sigma_{12}$. Introducing the divergence $D_D =
134	\dot{\epsilon}_{11}+\dot{\epsilon}_{22}$, and the horizontal tension
135	and shearing strain rates, $D_T =
136	\dot{\epsilon}_{11}-\dot{\epsilon}_{22}$ and $D_S =
137	2\dot{\epsilon}_{12}$, respectively, and using the above abbreviations,
138	the equations can be written as:
139	\begin{align}
140	\label{eq:evpstresstensor1}
141	\frac{\partial\sigma_{1}}{\partial{t}} + \frac{\sigma_{1}}{2T} +
142	\frac{P}{2T} &= \frac{P}{2T\Delta} D_D \\
143	\label{eq:evpstresstensor2}
144	\frac{\partial\sigma_{2}}{\partial{t}} + \frac{\sigma_{2} e^{2}}{2T}
145	&= \frac{P}{2T\Delta} D_T \\
146	\label{eq:evpstresstensor12}
147	\frac{\partial\sigma_{12}}{\partial{t}} + \frac{\sigma_{12} e^{2}}{2T}
148	&= \frac{P}{4T\Delta} D_S
149	\end{align}
150	Here, the elastic parameter $E$ is redefined in terms of a damping timescale
151	$T$ for elastic waves \[E=\frac{\zeta}{T}.\]
152	$T=E_{0}\Delta{t}$ with the tunable parameter $E_0<1$ and
153	the external (long) timestep $\Delta{t}$. \citet{hunke97} recommend
154	$E_{0} = \frac{1}{3}$.
155
156	For details of the spatial discretization, the reader is referred to
157	\citet{zhang98, zhang03}. Our discretization differs only (but
158	importantly) in the underlying grid, namely the Arakawa C-grid, but is
159	otherwise straightforward. The EVP model, in particular, is discretized
160	naturally on the C-grid with $\sigma_{1}$ and $\sigma_{2}$ on the
161	center points and $\sigma_{12}$ on the corner (or vorticity) points of
162	the grid. With this choice all derivatives are discretized as central
163	differences and averaging is only involved in computing $\Delta$ and
164	$P$ at vorticity points.
165
166	For a general curvilinear grid, one needs in principle to take metric
167	terms into account that arise in the transformation of a curvilinear
168	grid on the sphere. For now, however, we can neglect these metric
169	terms because they are very small on the \ml{[modify following
170	section3:] cubed sphere grids used in this paper; in particular,
171	only near the edges of the cubed sphere grid, we expect them to be
172	non-zero, but these edges are at approximately 35\degS\ or 35\degN\
173	which are never covered by sea-ice in our simulations. Everywhere
174	else the coordinate system is locally nearly cartesian.} However, for
175	last-glacial-maximum or snowball-earth-like simulations the question
176	of metric terms needs to be reconsidered. Either, one includes these
177	terms as in \citet{zhang03}, or one finds a vector-invariant
178	formulation for the sea-ice internal stress term that does not require
179	any metric terms, as it is done in the ocean dynamics of the MITgcm
180	\citep{adcroft04:_cubed_sphere}.
181
182	Lateral boundary conditions are naturally ``no-slip'' for B-grids, as
183	the tangential velocities points lie on the boundary. For C-grids, the
184	lateral boundary condition for tangential velocities is realized via
185	``ghost points'', allowing alternatively no-slip or free-slip
186	conditions. In ocean models free-slip boundary conditions in
187	conjunction with piecewise-constant (``castellated'') coastlines have
188	been shown to reduce in effect to no-slip boundary conditions
189	\citep{adcroft98:_slippery_coast}; for sea-ice models the effects of
190	lateral boundary conditions have not yet been studied.
191
192	Moving sea ice exerts a stress on the ocean which is the opposite of
193	the stress $\vtau_{ocean}$ in Eq.\refeq{momseaice}. This stess is
194	applied directly to the surface layer of the ocean model. An
195	alternative ocean stress formulation is given by \citet{hibler87}.
196	Rather than applying $\vtau_{ocean}$ directly, the stress is derived
197	from integrating over the ice thickness to the bottom of the oceanic
198	surface layer. In the resulting equation for the \emph{combined}
199	ocean-ice momentum, the interfacial stress cancels and the total
200	stress appears as the sum of windstress and divergence of internal ice
201	stresses: $\delta(z) (\vtau_{air} + \vek{F})/\rho_0$, \citep[see also
202	Eq.\,2 of][]{hibler87}. The disadvantage of this formulation is that
203	now the velocity in the surface layer of the ocean that is used to
204	advect tracers, is really an average over the ocean surface
205	velocity and the ice velocity leading to an inconsistency as the ice
206	temperature and salinity are different from the oceanic variables.
207
208	Sea ice distributions are characterized by sharp gradients and edges.
209	For this reason, we employ positive, multidimensional 2nd and 3rd-order
210	advection scheme with flux limiter \citep{roe85, hundsdorfer94} for the
211	thermodynamic variables discussed in the next section.
212
213	\subparagraph{boundary conditions: no-slip, free-slip, half-slip}
214
215	\begin{itemize}
216	\item transition from existing B-Grid to C-Grid
217	\item boundary conditions: no-slip, free-slip, half-slip
218	\item fancy (multi dimensional) advection schemes
219	\item VP vs.\ EVP \citep{hunke97}
220	\item ocean stress formulation \citep{hibler87}
221	\end{itemize}
222
223	\subsection{Thermodynamics}
224	\label{sec:thermodynamics}
225
226	In the original formulation the sea ice model \citep{menemenlis05}
227	uses simple thermodynamics following the appendix of
228	\citet{semtner76}. This formulation does not allow storage of heat
229	(heat capacity of ice is zero, and this type of model is often refered
230	to as a ``zero-layer'' model). Upward conductive heat flux is parameterized
231	assuming a linear temperature profile and together with a constant ice
232	conductivity. It is expressed as $(K/h)(T_{w}-T_{0})$, where $K$ is
233	the ice conductivity, $h$ the ice thickness, and $T_{w}-T_{0}$ the
234	difference between water and ice surface temperatures. The surface
235	heat flux is computed in a similar way to that of \citet{parkinson79}
236	and \citet{manabe79}.
237
238	The conductive heat flux depends strongly on the ice thickness $h$.
239	However, the ice thickness in the model represents a mean over a
240	potentially very heterogeneous thickness distribution. In order to
241	parameterize this sub-grid scale distribution for heat flux
242	computations, the mean ice thickness $h$ is split into seven thickness
243	categories $H_{n}$ that are equally distributed between $2h$ and
244	minimum imposed ice thickness of $5\text{\,cm}$ by $H_n=
245	\frac{2n-1}{7}\,h$ for $n\in[1,7]$. The heat flux for all thickness
246	categories is averaged to give the total heat flux.
247
248	The atmospheric heat flux is balanced by an oceanic heat flux from
249	below. The oceanic flux is proportional to
250	$\rho\,c_{p}\left(T_{w}-T_{fr}\right)$ where $\rho$ and $c_{p}$ are
251	the density and heat capacity of sea water and $T_{fr}$ is the local
252	freezing point temperature that is a function of salinity. Contrary to
253	\citet{menemenlis05}, this flux is not assumed to instantaneously melt
254	or create ice, but a time scale of three days is used to relax $T_{w}$
255	to the freezing point.
256
257	The parameterization of lateral and vertical growth of sea ice follows
258	that of \citet{hibler79, hibler80}.
259
260	On top of the ice there is a layer of snow that modifies the heat flux
261	and the albedo \citep{zhang98}. If enough snow accumulates so that its
262	weight submerges the ice and the snow is flooded, a simple mass
263	conserving parameterization of snowice formation (a flood-freeze
264	algorithm following Archimedes' principle) turns snow into ice until
265	the ice surface is back at $z=0$ \citep{leppaeranta83}.
266
267	Effective ich thickness (ice volume per unit area,
268	$c\cdot{h}$), concentration $c$ and effective snow thickness
269	($c\cdot{h}_{snow}$) are advected by ice velocities as described in
270	\refsec{dynamics}. From the various advection scheme that are
271	available in the MITgcm \citep{mitgcm02}, we choose flux-limited
272	schemes to preserve sharp gradients and edges and to rule out
273	unphysical over- and undershoots (negative thickness or
274	concentration). These scheme conserve volume and horizontal area.
275	\ml{[do we need to proove that? can we proove that? citation?]}
276
277	There is considerable doubt about the reliability of such a simple
278	thermodynamic model---\citet{semtner84} found significant errors in
279	phase (one month lead) and amplitude ($\approx$50\%\,overestimate) in
280	such models---, so that today many sea ice models employ more complex
281	thermodynamics. A popular thermodynamics model of \citet{winton00} is
282	based on the 3-layer model of \citet{semtner76} and treats brine
283	content by means of enthalphy conservation. This model requires in
284	addition to ice-thickness and compactness (fractional area) additional
285	state variables to be advected by ice velocities, namely enthalphy of
286	the two ice layers and the thickness of the overlying snow layer.
287	\ml{[Jean-Michel, your turf: ]Care must be taken in advecting these
288	quantities in order to ensure conservation of enthalphy. Currently
289	this can only be accomplished with a 2nd-order advection scheme with
290	flux limiter \citep{roe85}.}
291
292
293	\subsection{C-grid}
294	\begin{itemize}
295	\item no-slip vs. free-slip for both lsr and evp;
296	"diagnostics" to look at and use for comparison
297	\begin{itemize}
298	\item ice transport through Fram Strait/Denmark Strait/Davis
299	Strait/Bering strait (these are general)
300	\item ice transport through narrow passages, e.g.\ Nares-Strait
301	\end{itemize}
302	\item compare different advection schemes (if lsr turns out to be more
303	effective, then with lsr otherwise I prefer evp), eg.
304	\begin{itemize}
305	\item default 2nd-order with diff1=0.002
306	\item 1st-order upwind with diff1=0.
307	\item DST3FL (SEAICEadvScheme=33 with diff1=0., should work, works for me)
308	\item 2nd-order wit flux limiter (SEAICEadvScheme=77 with diff1=0.)
309	\end{itemize}
310	That should be enough. Here, total ice mass and location of ice edge
311	is interesting. However, this comparison can be done in an idealized
312	domain, may not require full Arctic Domain?
313	\item
314	Do a little study on the parameters of LSR and EVP
315	\begin{enumerate}
316	\item convergence of LSR, how many iterations do you need to get a
317	true elliptic yield curve
318	\item vary deltaTevp and the relaxation parameter for EVP and see when
319	the EVP solution breaks down (relative to the forcing time scale).
320	For this, it is essential that the evp solver gives use "stripeless"
321	solutions, that is your dtevp = 1sec solutions/or 10sec solutions
322	with SEAICE\_evpDampC = 615.
323	\end{enumerate}
324
325	\end{itemize}
326
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