Difference between revisions of "Sea-Ice Model"

The sea-ice component of ROMS is a combination of the elastic-viscous-plastic (EVP) rheology ( Hunke and Dukowicz, 1997, Hunke, 2001) and simple one-layer ice and snow thermodynamics with a molecular sublayer under the ice ( Mellor and Kantha, 1989). It is tightly coupled, having the same grid (Arakawa-C) and timestep as the ocean and sharing the same parallel coding structure for use with MPI or OpenMP.

Dynamics

The momentum equations describe the change in ice/snow velocity due to the combined effects of the Coriolis force, surface ocean tilt, air and water stress, and internal ice stress:

In this model, we neglect the nonlinear advection terms as well as the curvilinear terms in the internal ice stress. Nonlinear formulae are used for both the ocean-ice and air-ice surface stress:

The force due to the internal ice stress is given by the divergence of the stress tensor ${\displaystyle \sigma }$. The rheology is given by the stress-strain relation of the medium. We would like to emulate the viscous-plastic rheology of Hibler (1979):

where the nonlinear viscosities are given by

Hibler's ice strength is given by:

while Overland and Pease (1988): advocate a nonlinear strength:

in which ${\displaystyle P^{*}}$ now depends on the grid spacing. Both options are available in ROMS.

We would also like to have an explicit model that can be solved efficiently on parallel computers. The EVP rheology has a tunable coefficient ${\displaystyle E}$ (the Young's modulus) which can be chosen to make the elastic term small compared to the other terms. We rearrange the VP rheology:

then add the elastic term:

Much like the ocean model, the ice model has a split timestep. The internal ice stress term is updated on a shorter timestep so as to allow the elastic wave velocity to be resolved.

Once the new ice velocities are computed, the ice tracers can be advected using the MPDATA scheme ( Smolarkiewicz). The tracers in this case are the ice thickness, ice concentration, snow thickness, internal ice temperature, and surface melt ponds. The continuity equations describing the evolution of these parameters also include thermodynamic terms (${\displaystyle S_{h}}$, ${\displaystyle S_{s}}$ and ${\displaystyle S_{A}}$), described below:

The first two equations represent the conservation of ice and snow. The third is discussed in some detail in Mellor and Kantha, 1989, but represents the advection of ice blocks in which no ridging occurs as long as there is any open water.

The ice model variables:

Name	Description
${\displaystyle A(x,y,t)}$	ice concentration, ${\displaystyle 0.0\leq A\leq 1.0}$
${\displaystyle C_{a}}$	nonlinear air drag coefficient
${\displaystyle C_{d}=2.2\times 10^{-3}}$	air drag coefficient
${\displaystyle C_{w}=10\times 10^{-3}}$	water drag coefficient
${\displaystyle {\cal {D}}_{h},{\cal {D}}_{s},{\cal {D}}_{A}}$	diffusion terms
${\displaystyle \delta _{ij}}$	Kronecker delta function
${\displaystyle E}$	Young's modulus
${\displaystyle e=2}$	eccentricity of the elliptical yield curve
${\displaystyle \epsilon _{ij}(x,y,t)}$	strain rate tensor
${\displaystyle \eta (x,y,t)}$	nonlinear shear viscosity
${\displaystyle f(x,y)}$	Coriolis parameter
${\displaystyle {\cal {F}}_{x},{\cal {F}}_{y}}$	forces due to internal ice stress
${\displaystyle g}$	gravity
${\displaystyle H}$	Heaviside function
${\displaystyle h_{i}(x,y,t)}$	ice thickness
${\displaystyle h_{o}}$	ice cutoff thickness
${\displaystyle h_{s}(x,y,t)}$	snow thickness on ice-covered fraction
${\displaystyle M}$	ice mass, ${\displaystyle \rho _{i}Ah_{i}}$
${\displaystyle P}$	ice strength
${\displaystyle P^{*},C}$	ice strength parameters
${\displaystyle S_{h},S_{s},S_{A}}$	thermodynamic terms
${\displaystyle \sigma _{ij}}$	internal ice stress tensor
${\displaystyle {\vec {\tau }}_{a}}$	air stress
${\displaystyle {\vec {\tau }}_{w}}$	water stress
${\displaystyle u,v}$	the (${\displaystyle x,y}$) components of ice velocity ${\displaystyle {\vec {v}}}$
${\displaystyle {\vec {V}}_{10},{\vec {v}}_{w}}$	10 meter air and surface water velocities
${\displaystyle \zeta }$	nonlinear bulk viscosity
${\displaystyle \zeta _{w}}$	surface elevation of the underlying water

Note that Hibler's ${\displaystyle h_{I}}$ variable is equivalent to our ${\displaystyle Ah_{i}}$ combination - his ${\displaystyle h_{I}}$ is the average thickness over the whole gridbox while our ${\displaystyle h_{i}}$ is the average thickness over the ice-covered fraction of the gridbox.

Thermodynamics

The thermodynamics is based on calculating how much ice grows and melts on each of the surface, bottom, and sides of the ice floes, as well as frazil ice formation:

Once the ice tracers are advected, the ice concentration and thickness are timestepped according to the terms on the right:

The term ${\displaystyle Ah_{i}}$ is the "effective thickness", a measure of the ice volume. Its evolution equation is simply quantifying the change in the amount of ice. The ice concentration equation is more interesting in that it provides the partitioning between ice melt/growth on the sides vs. on the top and bottom. The parameter ${\displaystyle \Phi }$ controls this and has differing values for ice melt and retreat. In principle, most of the ice growth is assumed to happen at the base of the ice while rather more of the melt happens on the sides of the ice due to warming of the water in the leads.

The heat fluxes through the ice are based on a simple one layer Semtner (1976) type model with snow on top. The temperature is assumed to be linear within the snow and within the ice. The ice contains brine pockets for a total ice salinity of 3.2 or the surface ocean salinity, whichever is less. The surface ocean temperature and salinity is half a ${\displaystyle dz}$ below the surface. The water right below the surface is assumed to be at the freezing temperature; a logarithmic boundary layer is computed having the temperature and salinity matched at freezing.

Similarly, there is a snow equation:

where ${\displaystyle W_{s}}$ and ${\displaystyle W_{sm}}$ are the snowfall and snow melt rates, respectively, in units of equivalent water. Also in the model is the depth of the melt ponds in spring, ${\displaystyle h_{mp}}$ which can be up to 0.1 m, after which melting ice contributes to ${\displaystyle W_{ro}}$. The melt ponds are not part of the thermal conductivity computations. They could contribute to the albedo computation, but that has been largely commented out.

The ice model thermodynamic variables:

Name	Description
${\displaystyle \alpha _{w}=0.10}$	shortwave albedo of water
${\displaystyle \alpha _{i}=0.60}$	shortwave albedo of wet ice
${\displaystyle \alpha _{i}=0.65}$	shortwave albedo of dry ice
${\displaystyle \alpha _{s}}$	shortwave albedo of wet snow
${\displaystyle \alpha _{s}}$	shortwave albedo of dry snow
${\displaystyle C_{k}}$	snow correction factor
${\displaystyle C_{pi}}$ = 2093 J kg${\displaystyle ^{-1}}$ K${\displaystyle ^{-1}}$	specific heat of ice
${\displaystyle C_{po}}$ = 3990 J kg${\displaystyle ^{-1}}$ K${\displaystyle ^{-1}}$	specific heat of water
${\displaystyle \epsilon _{w}=0.97}$	longwave emissivity of water
${\displaystyle \epsilon _{i}=0.97}$	longwave emissivity of ice
${\displaystyle \epsilon _{s}=0.99}$	longwave emissivity of snow
${\displaystyle E(T,r)}$	enthalpy of the ice/brine system
${\displaystyle F_{T}\!\uparrow }$	heat flux from the ocean into the ice
${\displaystyle H\!\downarrow }$	sensible heat
${\displaystyle i_{w}}$	fraction of the solar heating transmitted through a lead into the water below
${\displaystyle k_{i}}$ = 2.04 W m${\displaystyle ^{-1}}$ K${\displaystyle {^{-}1}}$	thermal conductivity of ice
${\displaystyle k_{s}}$ = 0.31 W m${\displaystyle ^{-1}}$ K${\displaystyle {^{-}1}}$	thermal conductivity of snow
${\displaystyle L_{i}}$ = 302 MJ m${\displaystyle ^{-3}}$	latent heat of fusion of ice
${\displaystyle L_{s}}$ = 110 MJ m${\displaystyle ^{-3}}$	latent heat of fusion of snow
${\displaystyle LE\!\downarrow }$	latent heat
${\displaystyle LW\!\!\downarrow }$	incoming longwave radiation
${\displaystyle m}$ & ${\displaystyle -0.054^{\circ }}$C/PSU	coefficient in linear ${\displaystyle T_{f}(S)=mS}$ equation
${\displaystyle \Phi }$	contribution to ${\displaystyle A}$ equation from freezing water
${\displaystyle Q_{ai}}$	heat flux out of the snow/ice surface
${\displaystyle Q_{ao}}$	heat flux out of the ocean surface
${\displaystyle Q_{i2}}$	heat flux up out of the ice
${\displaystyle Q_{io}}$	heat flux up into the ice
${\displaystyle Q_{s}}$	heat flux up through the snow
${\displaystyle r}$	brine fraction in ice
${\displaystyle \rho _{i}}$ = 910 ${\displaystyle m^{3}/kg}$	density of ice
${\displaystyle S_{i}}$ = 3.2 PSU	salinity of the ice
${\displaystyle SW\!\!\downarrow }$	incoming shortwave radiation
${\displaystyle \sigma }$ = ${\displaystyle 5.67\times 10^{-8}}$ W m${\displaystyle ^{-2}}$ K${\displaystyle ^{-4}}$	Stefan-Boltzmann constant
${\displaystyle T_{0}}$	temperature of the bottom of the ice
${\displaystyle T_{1}}$	temperature of the interior of the ice
${\displaystyle T_{2}}$	temperature at the upper surface of the ice
${\displaystyle T_{3}}$	temperature at the upper surface of the snow
${\displaystyle T_{f}}$	freezing temperature
${\displaystyle T_{{\rm {melt}}\_i}}$ = ${\displaystyle mS_{i}}$	melting temperature of ice
${\displaystyle T_{{\rm {melt}}\_s}}$ = 0${\displaystyle ^{\circ }}$ C	melting temperature of snow
${\displaystyle W_{ai}}$	melt rate on the upper ice/snow surface
${\displaystyle W_{ao}}$	freeze rate at the air/water interface
${\displaystyle W_{fr}}$	rate of frazil ice growth
${\displaystyle W_{io}}$	freeze rate at the ice/water interface
${\displaystyle W_{ro}}$	rate of run-off of surface melt water
${\displaystyle W_{s}}$	snowfall rate
${\displaystyle W_{sm}}$	snow melt rate

The locations of the ice and snow temperatures and the heat fluxes:

The temperature profile is assumed to be linear between adjacent temperature points. The interior of the ice contains "brine pockets", leading to a prognostic equation for the temperature ${\displaystyle T_{1}}$.

The surface flux to the air is:

The incoming shortwave and longwave radiations are assumed to come from an atmospheric model. The formulae for sensible heat, latent heat, and outgoing longwave radiation are the same as in Parkinson and Washington (1979) and are shown in Radiant Heat Fluxes. The sensible heat is a function of ${\displaystyle T_{3}}$, as is the heat flux through the snow ${\displaystyle Q_{s}}$. Setting ${\displaystyle Q_{ai}=Q_{s}}$, we can solve for ${\displaystyle T_{3}}$ by setting ${\displaystyle T_{3}^{n+1}=T_{3}^{n}+\Delta T_{3}}$ and linearizing in ${\displaystyle \Delta T_{3}}$. As in Parkinson and Washington, if ${\displaystyle T_{3}}$ is found to be above the melting temperature, it is set to ${\displaystyle T_{\rm {melt}}}$ and the extra energy goes into melting the snow or ice:

Note that ${\displaystyle L_{3}=(1-r)L_{i}}$ plus a small sensible heat correction. We can store water on the surface in melt pools to a fixed depth---everything extra melted at the surface is assumed to flow into the ocean as ${\displaystyle W_{ro}}$. The melt ponds however do not contribute to the heat flux computation.

Inside the ice there are brine pockets in which there is salt water at the in situ freezing temperature. It is assumed that the ice has a uniform overall salinity of ${\displaystyle S_{i}}$ and that the freezing temperature is a linear function of salinity. The brine fraction ${\displaystyle r}$ is given by

The enthalpy of the combined ice/brine system is given by

Substituting in for ${\displaystyle r}$ and differentiating gives:

Inside the snow, we have

The heat conduction in the upper part of the ice layer is

These can be set equal to each other to solve for ${\displaystyle T_{2}}$

where

Substituting into (\ref{qi2}), we get:

Note that in the absence of snow, ${\displaystyle C_{k}}$ becomes zero and we recover the formula for the no-snow case in which ${\displaystyle T_{3}=T_{2}}$.

At the bottom of the ice, we have

The difference between ${\displaystyle Q_{I0}}$ and ${\displaystyle Q_{I2}}$ goes into the enthalpy of the ice:

We can use the chain rule to obtain an equation for timestepping ${\displaystyle T_{1}}$:

where

Ocean surface boundary conditions

The ocean receives surface stresses from both the atmosphere and the ice, according to the ice concentration:

where the relevant variables are in the following table:

Variable	Value	Definition
${\displaystyle b}$	3.14	factor
${\displaystyle {\dot {E}}}$		evaporation
${\displaystyle k}$	0.4	von Karman's constant
${\displaystyle K_{m}}$		vertical viscosity of seawater
${\displaystyle \nu }$	${\displaystyle 1.8\times 10^{-6}m^{2}s^{-1}}$	kinematic viscosity of seawater
${\displaystyle {\dot {P}}}$		precipitation
${\displaystyle Pr}$	13.0	molecular Prandtl number
${\displaystyle P_{rt}}$	0.85	turbulent Prandtl number
${\displaystyle S_{0}}$		surface salinity
${\displaystyle S}$		internal ocean salinity
${\displaystyle Sc}$	2432	molecular Schmidt number
${\displaystyle \tau _{io}}$		stress on the ocean from the ice
${\displaystyle \tau _{ao}}$		stress on the ocean from the wind
${\displaystyle T_{0}}$		surface ocean temperature
${\displaystyle T}$		internal ocean temperature
${\displaystyle u_{\tau }}$		friction velocity ${\displaystyle |\tau _{io}|^{1/2}\rho _{o}^{-1/2}}$
${\displaystyle z_{0}}$		roughness parameter

surface salinity (${\displaystyle T_{0}=mS_{0}}$) in the presense of ice. We also have ${\displaystyle T}$ and ${\displaystyle S}$ at the uppermost computed ocean point ${\displaystyle {1 \over 2}dz}$ below the surface. In order to solve for ${\displaystyle T_{0}}$ and ${\displaystyle S_{0}}$, we assume a Yaglom and Kader, 1974 logarithmic boundary layer. The upper ocean heat flux is:

where

Likewise, we have the following equation for the surface salt flux:

where

The ocean model receives the following heat and salt fluxes:

Mellor and Kantha describe solving simultaneously for the five unknowns ${\displaystyle W_{o}}$, ${\displaystyle T_{0}}$, ${\displaystyle S_{0}}$, ${\displaystyle F_{T}}$ and ${\displaystyle F_{S}}$. Instead, we use the old value of ${\displaystyle T_{0}}$ to find ${\displaystyle W_{io}}$ and therefore ${\displaystyle W_{o}}$. Using the new value of ${\displaystyle W_{io}}$, solve for a new value of ${\displaystyle S_{0}}$ and then find the new ${\displaystyle T_{0}}$ as the freezing temperature for that salinity:

Note that the term ${\displaystyle W_{ai}H(-W_{ai})}$ is the contribution of melting only, not refreezing of melt ponds.

Frazil ice formation

Following Steele et al. (1989), we check to see if any of the ocean temperatures are below freezing at the end of each timestep. If so, frazil ice is formed, changing the local temperature and salinity. The ice that forms is assumed to instantly float up to the surface and add to the ice layer there. We balance the mass, heat, and salt before and after the ice is formed:

The variables are defined in this table:

Variable	Value	Definition
${\displaystyle C_{pi}}$	1994 J kg${\displaystyle ^{-1}}$ K${\displaystyle ^{-1}}$	specific heat of ice
${\displaystyle C_{pw}}$	3987 J kg${\displaystyle ^{-1}}$ K${\displaystyle ^{-1}}$	specific heat of water
${\displaystyle \gamma }$	${\displaystyle m_{i}/m_{w_{2}}}$	fraction of water that froze
${\displaystyle L}$	3.16e5 J kg${\displaystyle ^{-1}}$	latent heat of fusion
${\displaystyle m_{i}}$		mass of ice formed
${\displaystyle m_{w_{1}}}$		mass of water before freezing
${\displaystyle m_{w_{2}}}$		mass of water after freezing
${\displaystyle m}$	${\displaystyle -0.0543}$	constant in freezing equation
${\displaystyle n}$	${\displaystyle 7.59\times 10^{-4}}$	constant in freezing equation
${\displaystyle S_{1}}$		salinity before freezing
${\displaystyle S_{2}}$		salinity after freezing
${\displaystyle T_{1}}$		temperature before freezing
${\displaystyle T_{2}}$		temperature after freezing

Defining ${\displaystyle \gamma =m_{i}/m_{w_{2}}}$ and dropping terms of order ${\displaystyle \gamma ^{2}}$ leads to:

We also want the final temperature and salinity to be on the freezing line, which we approximate as:

We can then solve for ${\displaystyle \gamma }$:

The ocean is checked at each depth ${\displaystyle k}$ and at each timestep for supercooling. If the water is below freezing, the temperature and salinity are adjusted as in equations (\ref{t2eq}) and (\ref{s2eq}) and the ice above is thickened by the amount: