6.34. initial_conditions.nml
¶
This file contains a single namelist called JULES_INITIAL
that is used to set up the initial state of prognostic variables.
6.34.1. JULES_INITIAL
namelist members¶
The values of all prognostic variables must be set at the start of a run. This initial state, or initial condition, can be read from a “dump” from an earlier run of the model, or may be read from a different file. Another option is to prescribe a simple or idealised initial state by giving constant values for the prognostic variables directly in the namelist. It is also possible to set some fields using values from a file (e.g. a dump) but to set others to constants given in the namelist.
- JULES_INITIAL::dump_file¶
- Type:
logical
- Default:
F
Indicates whether the given
file
is a dump from a previous run of JULES.- TRUE
The file is a JULES dump file.
- FALSE
The file is not a JULES dump file.
- JULES_INITIAL::total_snow¶
- Type:
logical
- Default:
F
Switch controlling simplified initialisation of snow variables.
- TRUE
Only the total mass of snow on each surface tile (see
snow_tile
in List of initial condition variables) is required to be input, and all related variables will be calculated from this or simple assumptions made. All the snow is assumed to be on the ground (not in the canopy).- FALSE
All snow variables required for the current configuration must be input separately (see List of initial condition variables).
6.34.1.1. List of initial condition variables¶
All input to the model must be on the same grid (see Input files for JULES), and initial conditions are no different. Even when the variable is only required for land points, values must be provided for the full input grid. Variables read as initial conditions must have no time dimension.
The variables it is possible to specify as initial conditions can be grouped into ‘types’ depending on the number and size of the levels dimensions they are required to have. For NetCDF files, the dimension names are those specified in the JULES_INPUT_GRID
namelist. For variables with no type specified, no levels dimensions should be used.
The required levels dimensions for each initial condition ‘type’ are given in the following table:
Type |
Number of levels dimensions |
Levels dimension name(s) |
Levels dimension size(s) |
---|---|---|---|
soil |
1 |
||
pft |
1 |
||
cpft |
1 |
||
type |
1 |
||
surft |
1 |
|
|
sclayer |
1 |
Number of soil biogeochemistry layers. If using the single-pool moodel
( If using the 4-pool model
( If using the ECOSSE model
( |
|
scpool |
2 |
number of soil carbon pools (1 if
|
|
bedrock |
1 |
Only applicable if |
|
snow |
2 |
Only applicable if |
The required variables for a particular configuration, along with their ‘type’ as specified above, are given in the following table.
Name |
Description |
Type |
---|---|---|
Always required |
||
|
Amount of intercepted water that is held on each surface tile (kg m-2). |
surft |
|
Soil carbon (kg m-2). If using the single-pool model ( Otherwise, this is the carbon in each of the 4 pools of the 4-pool or ECOSSE models. |
scpool |
|
If If If Further details of snow initialisation are given below. |
surft |
|
Temperature of each soil layer (K). |
soil |
|
Temperature of each surface tile (K). This is the surface or skin temperature. |
surft |
Required if |
||
|
Surface conductance for water vapour (m s-1). This is used to start the iterative calculation of gs for the first timestep only. |
None |
Required if |
||
|
Soil wetness for each soil layer. This is the mass of soil water (liquid and frozen), expressed as a fraction of the water content at saturation. |
soil |
Required if |
||
|
Leaf area index of each PFT. |
pft |
Required if |
||
|
Height (m) of each PFT. |
pft |
Required if |
||
|
Number of years since the previous harvest. |
pft |
Required if |
||
|
The fraction of land area of each gridbox that is covered by each surface type.
N.B. values specified here will override those at |
type |
Required if |
||
|
Unfrozen soil wetness of each layer as a fraction of saturation in irrigated fraction. |
soil |
Required if |
||
|
Development index for each crop pft. |
cpft |
|
Root carbon pool for each crop pft (kg m-2). |
cpft |
|
Carbon in ‘harvest parts’ pool for each crop pft (kg m-2) . |
cpft |
|
Carbon in stem reserves pool for each crop pft (kg m-2). |
cpft |
|
Leaf area index of each crop pft. |
cpft |
|
Height (m) of each crop pft. |
cpft |
Required if |
||
|
Soil wetness in the deep LSH/TOPMODEL layer beneath the standard soil column. This is the mass of soil water (liquid and frozen), expressed as a fraction of the water content at saturation. |
None |
|
Depth from the surface to the water table (m). |
None |
Required if |
||
|
Temperature of each bedrock layer (K) |
bedrock |
Required if |
||
|
Snow surface grain size (μm) on each surface tile. |
None |
Required if |
||
|
Bulk density of lying snow (kg m-3). If
|
surft |
|
Depth of snow (kg m). If |
surft |
Required if |
||
|
Amount of snow on the ground, beneath the canopy (kg m-2), on each surface tile. If |
surft |
Required if |
||
|
The number of snow layers on each surface tile. If |
surft |
|
Depth of snow in each layer (kg m). If |
snow |
|
Mass of frozen water in each snow layer (kg m-2). If |
snow |
|
Mass of liquid water in each snow layer (kg m-2). If |
snow |
|
Temperature of each snow layer (K). If |
snow |
Required if |
||
|
Snow grain size (μm) on each surface tile in each snow layer. If |
snow |
|
Gridbox agricultural/crop fraction from previous TRIFFID timestep. |
none |
|
Carbon content of the wood products pool with a fast decay rate. |
none |
|
Carbon content of the wood products pool with a medium decay rate. |
none |
|
Carbon content of the wood products pool with a slow decay rate. |
none |
Required if |
||
|
Gridbox pasture fraction from previous TRIFFID timestep. |
none |
Required if |
||
|
Gridbox bioenergy fraction from previous TRIFFID timestep. |
none |
Required if using 4-pool model ( |
||
|
Soil nitrogen (kg m-2). |
scpool |
Required if using 4-pool model ( |
||
|
Soil inorganic nitrogen (kg m-2). |
sclayer |
Required if using ECOSSE ( |
||
|
Soil ammonium (kg m-2). |
sclayer |
|
Soil nitrate (kg m-2). |
sclayer |
Required if |
||
|
Surface water storage on river routing points (m3) |
none |
|
Sub-surface water storage on river routing points (m3) |
none |
|
Surface flow into a grid box on river routing points (m3) |
none |
|
Sub-surface flow into a grid box on river routing points (m3) |
none |
Required if |
||
|
Water storage (kg) |
none |
Required if |
||
|
Running mean air temperature (K) |
none |
Warning
- if
l_rivers
= TRUE,i_river_vn
= ‘2’ anddump_file
= FALSE, rfm_surfstore_rp, rfm_substore_rp, rfm_flowin_rp and rfm_bflowin are initialised to zero.
Warning
if l_rivers
= TRUE, i_river_vn
= ‘1,3’ and dump_file
= FALSE,
rivers_sto_rp is initialised to zero.
6.34.2. Examples of specification of initial state¶
6.34.2.1. Specification of initial state at a single point¶
This assumes that l_phenol
= FALSE, l_triffid
= FALSE, soil_bgc_model
= 1 and nsmax
= 0.
&JULES_INITIAL
file = "initial_conditions.dat",
nvars = 8,
var = 'canopy' 'tstar_tile' 'cs' 'gs' 'rgrain' 'snow_tile' 'sthuf' 't_soil',
use_file = F F F F F F T T ,
const_val = 0.0 276.78 12.1 0.0 50.0 0.0
/
Or using the alternative list syntax (see Introduction to Fortran namelists):
&JULES_INITIAL
file = "initial_conditions.dat",
nvars = 8,
var(1) = 'canopy', use_file(1) = F, const_val(1) = 0.0 ,
var(2) = 'tstar_tile', use_file(2) = F, const_val(2) = 276.78,
var(3) = 'cs', use_file(3) = F, const_val(3) = 12.1,
var(4) = 'gs', use_file(4) = F, const_val(4) = 0.0,
var(5) = 'rgrain', use_file(5) = F, const_val(5) = 50.0,
var(6) = 'snow_tile', use_file(6) = F, const_val(6) = 0.0,
var(7) = 'sthuf', use_file(7) = T,
var(8) = 't_soil', use_file(8) = T,
/
This shows how a mixture of constant values and initial state from a file can be used. In this case, the first 6 variables will be set to constant values everywhere (use_file
= FALSE) with the last 2 read from the specified file (use_file
= TRUE).
file
specifies an ASCII file to read the variables for which use_file
= TRUE from.
Since the variables are arranged such that all those with use_file
= FALSE are first, we need only supply constant values for those variables that require them.
The contents of initial_conditions.dat
should look similar to:
# sthuf(1:4) t_soil(1:4)
0.749 0.743 0.754 0.759 276.78 277.46 278.99 282.48
The data for each soil layer is given in consecutive columns. A comment line is used to indicate which columns comprise which variable (see Input files for JULES for more details).
Specifying initial state for gridded data using NetCDF files is similar, except that:
6.34.2.2. Specification of initial state from an existing dump file¶
In this example, we use an existing dump file (from a previous run) to set the initial values of all required variables.
&JULES_INITIAL
dump_file = T,
file = "jules_dump.nc"
/
dump_file
= TRUE indicates that the given file should be interpreted as a JULES dump file.
file
specifies the dump file to read (in this case a NetCDF dump file).
Since it is not specified, nvars
takes its default value of 0, which indicates that JULES should attempt to read all required variables from the given dump file.