CESM G compset
Overview
Teaching: min
Exercises: minQuestions
How to run Ocean and Ice models?
Objectives
We will setup and run 4 ocean/sea-ice experiments to learn how to work with these components.
Ocean/ice active compsets start with G
.
Just like the F
compsets needed SST data as the boundary forcing, G
compsets require boundary forcing from the atmosphere. The standard atmospheric forcing provided to a G
compset is called CORE (Coordinated Ocean-ice Reference Experiments), version 2, atmopsheric datasets (Large and Yeager 2009)
G
: this is a standard ocean/ice with data atmosphere/land compset in which the boundary forcing is callednormal year forcing (NYF)
, meaning 12 months of CORE forcing data that repeats (think like a climatology).GIAF
: this is ocean/ice activate with data atmosphere/land in which the boundary forcing is interannually varying from CORE forcing data.
Our Experiments
Control Case: default settings, 1 year__
Setup, build, and run a control case for 1 year. Use the following:
compset
=G
resolution
=T62_g37
Overflow Parameterization Case
Create a case exactly the same as the control case, but with the overflow parameterization turned off.
This means we will not attempt to parameterize the mixing associated with dense water sinking in the Denmark Strait, Faroe Bank Channel, and Weddell and Ross Seas.
Modifying parameterizations is done in the namelists.
After we build the model or run ./preview_namelists
, the namelists that the model uses are located in:
/glade/scratch/USERNAME/CASENAME/run/xxx_in
Remember, when we want to make a change to a namelists, we use user_nl_xxx
to override the default behavior.
We can always run ./preview_namelists
to check our namelists get resolved properly.
To create an exact replica of another case, you can use create_clone
rather than create_newcase
, as follows, replacing NEWCASE
and OLDCASE
with the correct case names:
./create_clone --case ~/cases/NEWCASE --clone ~/cases/OLDCASE
Setup and build the case.
Modify the user_nl_pop
namelist as follows:
overflows_on = .false.
overflows_interactive = .false.
Run the case for 1 year.
Where do you expect the overflow parameterization to matter?
What variables would you look at in your output?
Change the snow albedo on sea ice case
Create a clone of your control simulation.
Modify user_nl_cice
as follows:
r_snw = 2.00
This is a tuning parameter that specifies the number of standard deviations away from the base optical properties in the shortwave
radiative transfer code. The default value is -2.00. It is used in the equation: rsnw_nonmelt = 500 - r_snw * 250
(in microns).
Higher values of r_snw -> lower rsnw_nonmelt -> higher albedo.
Run the model for 1-year.
What do you think will happen by increasing the albedo of the ice?
How can you check?
Some variables to look at:
albedo to convince yourself this worked as expected
ice fraction to see how changing albedo impacted the ice
Increase the zonal wind stress in the ocean case
Create a clone of your control simulation
Run case.setup
This exercise demonstrates how to change the source code (i.e. Fortran) of the model. The original source code resides in:
/glade/work/USERNAME/cesm2.1.3/
Similar to namelists, we don’t change the original, we make changes in an alternate location, then modify it to override the default. Changes to source code go in SourceMods/src.xxx
Also, source code changes must be included in the build, so we make the changes before building the model.
Copy the file /glade/work/USERNAME/cesm2.1.3/components/pop/source/forcing_coupled.F90
to CASEDIR/SourceMods/src.pop/
cp /glade/work/USERNAME/cesm2.1.3/components/pop/source/forcing_coupled.F90 ~/cases/gwindstress/SourceMods/src.pop/
Now let’s look at the code.
Find the subroutine rotate_wind_stress
This code rotates the wind stress vector to map it onto the correct location in the model local grid coordinates. We can think of the first component (array index 1) as the zonal direction (on the model grid) and the second component (array index 2) as the meridional component on the model local grid coordinates.
Add a line of code to increase the first component by 25%.
Build and run the model for 1-year.
Be sure to check that the model built successfully before you run it. If you had a typo, you will likely get a build error and your model will not run because it did not build.
Where do you think there will be the biggest impacts of increased zonal wind stress?
How can you check the impact?
What variables would you look at?
Looking at our output
Once you have submitted your model runs, they will run relatively quickly if the queue is not too busy. In the meantime, you can look at the output of my model runs to explore the results of these experiments.
Experiment 1 (control): /glade/scratch/cstan/archive/gcontrol/ocn/hist/
Experiment 2 (overflow): /glade/scratch/cstan/archive/goverflow/ocn/hist/
Experiment 3 (snow albedo): /glade/scratch/cstan/archive/gsnowalb/ice/hist
Experiment 4 (wind stress): /glade/scratch/cstan/archive/gwindstress/ocn/hist
How would we read this data?
To launch the Jupyter notebook on the NCAR computers
- Log in to the Production NCAR JupyterHub
- Start a server
import xarray as xr
path='/glade/scratch/cstan/archive/gcontrol/ocn/hist/'
files='gcontrol.pop.h.0001-*.nc'
ds=xr.open_mfdataset(path+files,combine='nested',
concat_dim='time')
ds
We can look at annual mean values by taking the mean in time.
ds_amean=ds.mean(dim='time')
Key Points