|
|
|
|
|
This slide show describes several Atlantic Ocean
simulations performed using HYCOM with different vertical mixing schemes
and with both hybrid and isopycnic vertical coordinates. Properties of
HYCOM are outlined first. Model performance is then evaluated by comparing
simulated fields to each other, to observed fields (Levitus climatology),
and to fields simulated by the Miami Isopycnic Coordinate Ocean Model
(MICOM). |
|
|
|
|
|
Press button to jump forward to each section: |
|
|
|
I. The Model |
|
2. Model Simulations |
|
3. Surface/Mixed Layer Thermodynamical Fields |
|
4. Surface/Mixed Layer Dynamical Fields |
|
5. Cross-Sections |
|
6. Model Censuses |
|
7. Meridional Overturning Circulation and Heat
Flux |
|
8. Regional Differences in Upper Ocean
Variability |
|
9. Regional Mixed Layer Profiles |
|
10. Summary |
|
11. Referencess |
|
|
|
|
|
|
|
|
|
|
History |
|
Developed from MICOM version 2.8 |
|
See Bleck (1998) for a description of MICOM |
|
Hybrid coordinate scheme used in HYCOM |
|
Model equations written in generalized vertical
coordinates |
|
Originally used in the Bleck and Boudra (1981)
quasi-isopycnic model |
|
Numerical schemes could not handle zero
thickness layers |
|
Minimum layer thickness was enforced |
|
The vertical coordinate became non-isopycnic in
regions where the layers became too thin |
|
A hybrid (isentropic-sigma) vertical coordinate
was used in the atmospheric model of Bleck and Benjamin (1993) |
|
The HYCOM isopycnic-level-sigma vertical
coordinate scheme is an adaptation and extension of the Bleck/Benjamin
algorithm |
|
|
|
|
|
Major changes from MICOM |
|
New vertical coordinate scheme |
|
Multiple mixed layer models, including non-slab
models |
|
Interior convection due to static instability
(two layers exchange fluid when the upper one is more dense) |
|
Hydrostatic and momentum equations modified to
handle non-isopycnic densities and horizontal density gradients |
|
Choice of temperature-salinity,
temperature-density, or salinity-density advection |
|
|
|
|
|
|
|
|
Vertical Coordinates |
|
Hybrid coordinates |
|
Nearsurface: z-coordinates |
|
Shallow water: sigma (terrain-following)
coordinates |
|
Coordinates are isopycnic in the bulk of the
ocean interior |
|
Isopycnic coordinates (MICOM mode) |
|
Hybrid Vertical Coordinate Scheme (part 1) |
|
In the open ocean, the coordinates are isopycnic
except year the surface where minimum coordinate separation is enforced.
The minimum separation differs for each layer, giving the user great
flexibility to set the vertical coordinate structure in the z-coordinate
domain. |
|
A cushion function described in Bleck and
Benjamin (1993) provides a smooth transition between the isopycnic and
z-coordinate domains. |
|
To activate the sigma coordinate domain, the
user specifies the number of sigma coordinates n and the coordinate
separation d. Vertical coordinates become terrain-following where bottom
depth is less than n*d. In extremely shallow water, the coordinates revert
to level coordinates. |
|
|
|
|
|
|
|
Hybrid Vertical Coordinate Scheme (part 2) |
|
In the deep ocean, the isopycnic-level
coordinate transition is performed as follows: |
|
If the density of a given layer does not equal
the isopycnic reference density, the interfaces bounding the layer are
adjusted to return the density to its reference value |
|
If the layer is too light, the interface below
is moved downward so that the entrained denser water returns the density to
its reference value |
|
If the layer is too dense, the interface above
is moved upward in the same manner |
|
If minimum coordinate separation is violated
near the ocean surface, the cushion function is used to re-calculate the
vertical coordinate location, prohibiting the restoration of isopycnic
conditions. |
|
Two of the thermodynamical variables T, S, and
density are mixed across the moving interfaces (user selectable), with the
third calculated from the equation of state. If T and S are mixed, exact
isopycnal density is not restored, but repeated application keeps the error
small. |
|
|
|
|
|
Horizontal Advection |
|
Two of the thermodynamical variables T, S, and
density are advected (user selectable), with the third calculated from the
equation of state. |
|
If HYCOM is run in MICOM mode, advection is
performed as in MICOM 2.8, with T and S advected in layer 1 (the mixed
layer) and S only advected in the isopycnic layers. |
|
|
|
|
|
|
|
|
|
|
|
Mixing Schemes |
|
K-Profile Parameterization |
|
Kraus-Turner Mixed Layer Model |
|
Two Kraus-Turner mixed layer models available
for hybrid coordinates |
|
A third Kraus-Turner model is available when
HYCOM is run in MICOM mode |
|
Handles detrainment of water into isopycnic
layers |
|
Same algorithm used in MICOM 2.8 |
|
With hybrid coordinates, choice of explicit
(MICOM-like) or implicit (KPP-like) interior diapycnal mixing |
|
|
|
|
|
|
|
K-Profile Parameterization (KPP) |
|
Developed by Large, Mc Williams, and Doney
(1994) |
|
Governs Vertical Mixing of Entire Water Column |
|
Parameterizes Several Physical Processes |
|
Surface boundary layer |
|
Mechanical wind mixing |
|
Buoyancy flux forcing |
|
Convective overturning |
|
Non-local (counter-gradient) fluxes |
|
Diapycnal mixing in ocean interior |
|
Instability due to resolved vertical shear |
|
Background internal wave mixing |
|
Double diffusion mixing (diffusive convection
and salt fingering) |
|
Can Run at Relatively Low Vertical Resolution |
|
|
|
|
|
|
|
|
|
|
KPP Procedure (part 1): |
|
Apply surface thermodynamical and momentum flux
forcing |
|
Calculate K profiles for interior diapycnal
mixing from surface to bottom |
|
Diagnose turbulent boundary layer thickness |
|
Minimum depth H where a bulk Richardson number
exceeds critical value |
|
Turbulent boundary layer eddies can penetrate to
depth H where the fluid becomes stable relative to local buoyancy and
velocity |
|
|
|
|
|
|
|
KPP Procedure (part 2) |
|
Calculate surface boundary layer k profiles for
T, S, and momentum |
|
Vertical diffusivity for T is parameterized as |
|
|
|
where
is the nonlocal transport term |
|
Diffusivity is parameterized as |
|
where w is a turbulent velocity scale that is a
function of the stability of the forcing, G is a 3rd order
polynomial shape function, and sigma is a scale depth varying from 0 to 1
over the depth range H |
|
Choose coefficients of G to match the interior
and boundary layer K profiles, producing a final K profile with a
continuous first vertical derivative |
|
Solve diffusion equation semi-implicitly with
two temporal iterations |
|
Diagnose mixed layer thickness along with T, S,
u, and v |
|
|
|
|
|
|
|
|
|
Implementation of Kraus-Turner mixing with
hybrid coordinates |
|
Mixed layer base is not a vertical coordinate
interface as in MICOM |
|
Must keep track of T, S, and density jumps
across the mixed layer base |
|
|
|
|
|
|
|
|
Two hybrid-coordinate K-T mixed layer models
have been developed. |
|
K-T 1: Full model |
|
This version has a prognostic mixed layer base.
At a given grid point, the base is contained within layer k and divides
this layer into two sublayers (see diagram on previous slide). T and S are
estimated within these sublayers by “unmixing” each variable, then the TKE
balance is calculated as in the MICOM K-T mixed layer. |
|
K-T 2: Simplified model |
|
This version was developed by Rainer Bleck to
avoid unmixing and the associated computational overhead. At each grid
point, the mixed layer base always resides on a vertical coordinate
interface. |
|
When HYCOM is run in MICOM mode, the MICOM 2.8
Kraus-Turner mixed layer model is used. The mixed layer base coincides with
vertical coordinate interface 2 (layer 1 is the slab mixed layer). Another
major difference from the hybrid-coordinate K-T models is the detrainment
algorithm, since the density of detrained water must match the isopycnic
reference density of the layer accepting the water. |
|
|
|
|
|
|
General Properties of Model Simulations |
|
Domain |
|
Atlantic Ocean basin, 20S to 62N |
|
Resolution: 2 degrees horizontal, 22 layers
vertical |
|
Forcing |
|
Climatological annual cycle forcing derived from
COADS |
|
Driven by vector wind stress, wind speed, air
temperature and humidity, precipitation, longwave and shortwave surface
radiation |
|
Model runs and analysis |
|
25-year spinup from zonally-averaged climatology
[p(lat)] derived from Levitus climatology |
|
One-year and five-year analysis runs with fields
archived monthly |
|
Analyze year 26, winter (Feb.) and summer (Aug.) |
|
Analyze 5-year time series, years 26-30 |
|
Minimum layer thickness in the z-coordinate
domain set to 10 m for all layers |
|
|
|
|
|
|
|
|
Primary Comparisons: |
|
Five model simulations compared to Levitus
climatology |
|
HYCOM KPP |
|
HYCOM KPP (theta-S) |
|
HYCOM K-T Implicit |
|
HYCOM K-T MICOM Mode |
|
HYCOM K-T Explicit |
|
The primary comparisons evaluate the primary
vertical mixing schemes plus the consequences of selecting theta-S
advection (where T is not conserved) instead of T-S advection |
|
|
|
Other Comparisons: |
|
HYCOM K-T MICOM mode vs. MICOM 2.8 |
|
Demonstrates expected strong similarity between
the models |
|
HYCOM K-T 1 vs. HYCOM K-T 2 |
|
Compare performance of the two hybrid K-T mixed
layer models |
|
HYCOM KPP (Rlx. BC) vs. Levitus Climatology |
|
Compare “most realistic” simulation to
observations |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Primary Comparisons: |
|
Five model simulations compared to Levitus
climatology |
|
HYCOM KPP |
|
HYCOM KPP (theta-S) |
|
HYCOM K-T Implicit |
|
HYCOM K-T MICOM Mode |
|
HYCOM K-T Explicit |
|
The primary comparisons evaluate the primary
vertical mixing schemes plus the consequences of selecting theta-S
advection (where T is not conserved) instead of T-S advection |
|
Other Comparisons: |
|
HYCOM K-T MICOM mode vs. MICOM 2.8 |
|
Demonstrates expected strong similarity between
the models |
|
HYCOM K-T 1 vs. HYCOM K-T 2 |
|
Compare performance of the two hybrid K-T mixed
layer models |
|
HYCOM KPP (Rlx. BC) vs. Levitus Climatology |
|
Compare “most realistic” simulation to
observations |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Primary Comparisons: |
|
Five model simulations compared to Levitus
climatology |
|
HYCOM KPP |
|
HYCOM KPP (theta-S) |
|
HYCOM K-T Implicit |
|
HYCOM K-T MICOM Mode |
|
HYCOM K-T Explicit |
|
The primary comparisons evaluate the primary
vertical mixing schemes plus the consequences of selecting theta-S
advection (where T is not conserved) instead of T-S advection |
|
Other Comparisons: |
|
HYCOM K-T MICOM mode vs. MICOM 2.8 |
|
Demonstrates expected strong similarity between
the models |
|
HYCOM K-T 1 vs. HYCOM K-T 2 |
|
Compare performance of the two hybrid K-T mixed
layer models |
|
HYCOM KPP (Rlx. BC) vs. Levitus Climatology |
|
Compare “most realistic” simulation to
observations |
|
|
|
|
|
|
|
The comparisons described in the previous slide
will be presented for meridional cross-sections at 33W. |
|
Other cross-sections are also presented |
|
65W to focus on the subtropical mode water |
|
Equator to focus on the equatorial current
structure |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Two types of model censuses were conducted: |
|
Layer thickness and total heat content evolution
during model spinup |
|
Documents climate drift during spinup |
|
Volumetric T-S censuses |
|
Illustrates water mass distribution |
|
|
|
|
|
|
|
The following three slides illustrate layer
thickness and total heat content evolution during the 25-year spinups of
six of the HYCOM simulations. |
|
Results are similar for all six cases. |
|
Model adjustments in the upper ocean have been
largely completed after the 25-year spinup |
|
Significant adjustments of intermediate and deep
water are still occurring after 25 years. These large adjustments occur in
part because the p(lat) initialization was not accurate at these depths. |
|
The subsequent four slides present the
volumetric T-S censuses. |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
In the following slide, the annual cycle of
meridional heat flux is contoured as a function of month and latitude for
five of the HYCOM simulations. |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Time series of upper-ocean variability are
presented for the eight model grid points shown on the following slide. The
points are: |
|
NAC (North Atlantic Current) |
|
STMW (Subtropical Mode Water formation region) |
|
SARG (Sargasso Sea, interior western subtropical
gyre) |
|
ESTG (interior eastern subtropical gyre) |
|
EBC (subtropical eastern boundary current) |
|
CRBN (Caribbean Sea) |
|
TRDW (North Atlantic Trade Winds) |
|
EQTR (Equator) |
|
Two sets of analysis are presented for
temperature |
|
One year time series |
|
Five year time series |
|
Three cases are compared |
|
HYCOM KPP |
|
HYCOM K-T Implicit |
|
HYCOM MICOM Mode |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Time series of upper-ocean variability are
presented for the ten model grid points shown on the following slide. The
points are: |
|
LABS (Labrador Sea) |
|
SLOP (Slope Water) |
|
NAC (North Atlantic Current) |
|
STMW (Subtropical Mode Water formation region) |
|
SARG (Sargasso Sea, interior western subtropical
gyre) |
|
ESTG (interior eastern subtropical gyre) |
|
EBC (subtropical eastern boundary current) |
|
CRBN (Caribbean Sea) |
|
TRDW (North Atlantic Trade Winds) |
|
EQTR (Equator) |
|
Two cases are compared |
|
HYCOM KPP |
|
HYCOM MICOM Mode |
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
The use of hybrid vertical coordinates and
improved vertical mixing algorithms improved the quality of model
simulations. |
|
Improved representation of subtropical mode
water. |
|
Improved horizontal mixed layer salinity
distribution in the subtropical gyre. |
|
Improved resolution of tropical upper-ocean
flow. |
|
Explicit resolution of upper-ocean wind driven
flow |
|
HYCOM run in MICOM mode produced results
extremely close to MICOM 2.8, indicating that code changes in HYCOM did not
degrade the quality of the solution. |
|
Many observed shortcomings of these HYCOM
simulations can be traced to the lack of an ice model, surface forcing
errors, the simple initial conditions, and the lack of river runoff. |
|
The choice of which two thermodynamical
variables are advected and also mixed in the vertical coordinate adjustment
algorithm did not have a noticeable influence on the solutions even though
in the KPP (theta-S) experiment, temperature was not conserved. |
|
|
|
|
Bleck, R., 1998: Ocean modeling in isopycnic
coordinates. Chapter 18 in Ocean Modeling and Parameterization, E. P.
Chassignet and J. Verron, Eds., NATO Science Series C: Mathematical and
Physical Sciences, Vol. 516, Kluwer Academic Publishers, 4223-448. |
|
|
|
Bleck, R. and D. Boudra, 1981: Initial testing
of a numerical ocean circulation model using a hybrid (quasi-isopycnic)
vertical coordinate. J. Phys. Oceanogr., 11, 755-770. |
|
|
|
Bleck, R. and S. Benjamin, 1993: Regional
weather prediction with a model combining terrain-following and isentropic
coordinates, Part 1: Model description. Mon. Wea. Rev., 121, 1770-1785. |
|
|
|
Large, W. G., J. C. Mc Williams, and S. C.
Doney, 1994: Oceanic vertical mixing: a review and a model with a nonlocal
boundary layer parameterization. Rev. Geophys. 32, 363-403. |
|
|
|
Notes