6.6. jules_surface.nml
¶
This file sets the surface options. It contains one namelist called JULES_SURFACE
.
6.6.1. JULES_SURFACE
namelist members¶
-
JULES_SURFACE::
all_tiles
¶ Type: integer Permitted: 0,1 Default: 0 Perform calculations of tile properties on all tiles (except land ice) for all gridpoints even when the tile fraction is zero.
- Off
- On
-
JULES_SURFACE::
cor_mo_iter
¶ Type: integer Permitted: 1-4 Default: 1 Corrections to Monin-Obukhov surface exchange calculation. Please see also UMDP24 “The Parametrization of Boundary Layer Processes” (section 8.4.1).
- Correct convective gustiness in low winds
- Correct U* in dust scheme,
- Limit Obukhov length in low winds
- Improve the initialisation of the iteration
Note
Option 4 should be the preferred option.
-
JULES_SURFACE::
beta_cnv_bl
¶ Type: real Permitted: >=0.0 Dimensionless coefficient scaling the boundary layer convective gustiness contribution to surface exchange. Historically this was set to 0.08 but is recommended to be reduced to 0.04 when gustiness from convective downdraughts is included, either from the convection parametrization or when convection is resolved (so resolutions ~1km or finer). Please see also UMDP24 “The Parametrization of Boundary Layer Processes” (section 8.1).
-
JULES_SURFACE::
l_aggregate
¶ Type: logical Default: F Switch controlling number of tiles for each gridbox.
This is used to set the number of surface energy balances that are solved for each gridbox (
ntiles
).- TRUE
- Aggregate parameter values are used to solve a single energy balance per gridbox. This option sets
ntiles = 1
. - FALSE
- A separate energy balance is calculated for each surface type. This option sets
ntiles = ntype
.
-
JULES_SURFACE::
i_aggregate_opt
¶ Type: integer Permitted: 0-1 Default: 0 Option for aggregating surface properties to tiles:
- Aggregate momentum roughness lengths and set the thermal roughness length as a given fraction of this (in practice the ratio of roughness lengths for the first surface type).
- Aggregate the thermal roughness lengths separately from the momentum roughness lengths using an analogous algorithm.
Note
This option is ignored unless
l_aggregate
is true.
-
JULES_SURFACE::
l_epot_corr
¶ Type: logical Default: F - TRUE
- Use correction to the calculation of potential evaporation.
- FALSE
- No effect.
-
JULES_SURFACE::
l_point_data
¶ Type: logical Default: F Flag indicating if driving data are point or area-average values. This affects the treatment of precipitation input and how snow affects the albedo.
- TRUE
- Driving data are point data. Precipitation is not distributed in space (see FALSE below) and is all assumed to be large-scale in origin. The albedo formulation is suitable for a point.
- FALSE
- Driving data are area averages. The precipitation inputs are assumed to be exponentially distributed in space, as in UMDP25, and can include convective and large-scale components. The albedo formulation is suitable for a gridbox.
-
JULES_SURFACE::
l_land_ice_imp
¶ Type: logical Default: F Switch to control the use of implicit numerics to update land ice temperatures.
- TRUE
- Use implicit numerics to update land ice temperatures.
- FALSE
- Use explicit numerics to update land ice temperatures.
-
JULES_SURFACE::
l_anthrop_heat_src
¶ Type: logical Default: F Switch for inclusion of anthropogenic contribution to the surface heat flux from urban surface types. If
l_urban2t
then the anthropogenic heat will be distributed between theurban_canyon
andurban_roof
according toanthrop_heat_scale
, otherwise it is added tourban
only.- TRUE
- Add anthropogenic effect.
- FALSE
- No effect.
-
JULES_SURFACE::
iscrntdiag
¶ Type: integer Permitted: 0-3 (standalone: 0 or 1 only) Default: 0 Switch controlling method for diagnosing screen temperature.
- Use surface similarity theory (no decoupling).
- Use surface similarity theory but allow decoupling in very stable conditions based on the quasi-equilibrium radiative solution.
- Diagnose the screen temperature including transient effects and radiative cooling.
- Diagnose the screen temperature and humidity including transient effects and radiative cooling. The diagnosis of the screen temperature follows option 2. This is an experimental option and is undergoing development and additional testing.
Note
Option 0 should be the preferred option in standalone i.e. no decoupling until the decoupled options are fully tested in standalone scenarios.
-
JULES_SURFACE::
l_elev_lw_down
¶ Type: logical Default: false If tiles are set to be at an elevation offset from the gridbox mean altitude (see
JULES_SURF_HGT
) this switch controls whether downwelling longwave radiation is adjusted along with surface air temperature and relative humidity.If true, the downwelling longwave for each tile not at the gridbox mean height is adjusted by an amount proportional to the fourth power of the adjustment that has been made to the surface air temperature. The adjustments are then scaled such that the sum over all tiles conserves the gridbox mean energy in the original forcing.
-
JULES_SURFACE::
l_elev_land_ice
¶ Type: logical Default: false Allows multiple ice tiles to exist in an ice gridbox, usually with each representing a different elevation (
JULES_SURF_HGT
) band on in icesheet areas so that a sub-gridscale surface mass balance term (a strong function of altitude) can be derived for forcing icesheet/glacier models. When enabled, ice tiles in a gridbox do not use the usual (gridbox mean) JULES soil/ice subsurface model, but each tile has an independent single layer bedrock-type solid ice boundary condition under the snowpack.In addition, when selected, dense snowpacks on elevated ice gridboxes are parameterised to behave more like firn in two ways: 1) The meltwater-holding capacity of snow layers reduces as a linear function of their density, becoming zero above the pore-closure density of 850 kg/m^2 so as to restrict retention of melt within the snowpack. 2) Where the top few centimetres of the pack has a density appropriate to firn/bare ice and the grain-size physics otherwise used for snow albedo become less appropriate, surface albedo becomes a function of density, tending towards that of bare ice as density increases (see
rho_firn_albedo
,amax
,aicemax
).If this scheme is enabled, a depth for the bedrock layer must be provided (
dzsoil_elev
) and the new tile numbers must be specified (JULES_SURFACE_TYPES
) as either typeelev_ice
(for fully glaciated areas) orelev_rock
(for non-glaciated areas where the bedrock may become exposed under a thin snow layer). The total number of non-vegetated tiles, and their surface properties (JULES_NVEGPARM
, usually set to be the same as the normal ice tile) must be set accordingly, as with any tile.
-
JULES_SURFACE::
l_urban2t
¶ Type: logical Default: false Switch for using the two-tile urban schemes (including MORUSES). This allows two urban tiles (
urban_canyon
andurban_roof
) to be used instead of one. Additional parameters must be supplied viaJULES_NVEGPARM
, with some able to be provided by MORUSES (seeJULES_URBAN_SWITCHES
).
Surface parameters
-
JULES_SURFACE::
hleaf
¶ Type: real Default: 5.7e4 Specific heat capacity of leaves (J K-1 per kg carbon).
See Hadley Centre Technical Note 30, p6, available from the Met Office Library.
-
JULES_SURFACE::
hwood
¶ Type: real Default: 1.1e4 Specific heat capacity of wood (J K-1 per kg carbon).
See Hadley Centre Technical Note 30, p6, available from the Met Office Library.
-
JULES_SURFACE::
beta1
¶ Type: real Default: 0.83 Coupling coefficient for co-limitation in photosynthesis model.
See Cox et al. (1999), Eq.61.
-
JULES_SURFACE::
beta2
¶ Type: real Default: 0.93 Coupling coefficient for co-limitation in photosynthesis model.
See Cox et al. (1999), Eq.61.
-
JULES_SURFACE::
fwe_c3
¶ Type: real Default: 0.5 Constant in expression for limitation of photosynthesis by transport of products, for C3 plants.
See Cox et al. (1999) Eq.60.
-
JULES_SURFACE::
fwe_c4
¶ Type: real Default: 20000.0 Constant in expression for limitation of photosynthesis by transport of products, for C4 plants.
See Cox et al. (1999) Eq.60.