6.7. jules_vegetation.nml
This file sets the vegetation options. It contains one namelist called JULES_VEGETATION.
6.7.1. JULES_VEGETATION namelist members
-
JULES_VEGETATION::l_q10
-
Switch for use of Q10 approach when calculating soil respiration.
- TRUE
Use Q10 approach.
Note
This is always used if TRIFFID is switched off (l_triffid = FALSE) and was used in JULES2.0.
- FALSE
- Use the approach of the RothC model.
-
JULES_VEGETATION::l_trait_phys
-
Switch for using trait-based physiology.
- TRUE
- Vcmax is calculated based on observed leaf traits. Leaf nitrogen (nmass: kgN kgLeaf-1) and leaf mass (LMA: kgLeaf m-2) can be based on observations from the TRY database. Vcmax (umol CO2 m-2 s-1) is based on linear regressions as in Kattge et al. 2009. Two additional parameters are needed: vint and vsl - the intercept and slope, respectively, that relate the leaf nitrogen to vcmax. Sigl is replaced with LMA (sigl=LMA*Cmass, where Cmass is the kgC/kgLeaf and is 0.4).
- FALSE
- Vcmax is calculated based on parameters nl0 (kgN kgC-1) and neff.
Note
Trait based physiology is not currently compatible with the crop model.
-
JULES_VEGETATION::l_phenol
-
Switch for vegetation phenology model.
- TRUE
- Use phenology model.
- FALSE
- Do not use phenology model.
-
JULES_VEGETATION::l_triffid
-
Switch for dynamic vegetation model (TRIFFID) except for competition.
- TRUE
- Use TRIFFID. In this case soil carbon is modelled using four pools
(biomass, humus, decomposable plant material, resistant plant material).
- FALSE
- Do not use TRIFFID. A single soil carbon pool is used.
-
JULES_VEGETATION::l_veg_compete
-
Switch for competing vegetation.
Only used if l_triffid = TRUE.
- TRUE
- TRIFFID will let the different PFTs compete against each other and modify the vegetation fractions.
- FALSE
- Vegetation fractions do not change.
-
JULES_VEGETATION::l_ht_compete
-
Only used if l_triffid = TRUE.
- TRUE
Use height-based vegetation competition.
This allows for a generic number of PFTs, and is implemented by lotka_noeq_jls.F90 and lotka_eq_jls.F90 depending on the setting of l_trif_eq.
- FALSE
Use the standard competition.
This is hard-wired for 5 PFTs with co-competition for grasses and trees in lokta_jls.F90.
-
JULES_VEGETATION::l_nitrogen
-
Only used if l_triffid = TRUE.
- TRUE
- Enable Nitrogen limitation of carbon uptake. A nitrogen deposition field should be provided otherwise no N deposition is assumed.
- FALSE
- No Nitrogen limitation. Nitrogen fluxes are calculated as diagnostics only.
-
JULES_VEGETATION::l_trif_eq
-
Switch for equilibrium vegetation model (i.e., an equilibrium solution of TRIFFID).
Only used if l_triffid = TRUE.
- TRUE
- Use equilibrium TRIFFID.
- FALSE
- Do not use equilibrium TRIFFID.
-
JULES_VEGETATION::phenol_period
Type: | integer |
Permitted: | >= 1 |
Default: | None |
Period for calls to phenology model in days. Only relevant if l_phenol = TRUE.
-
JULES_VEGETATION::triffid_period
Type: | integer |
Permitted: | >= 1 |
Default: | None |
Period for calls to TRIFFID model in days. Only relevant if one of l_triffid or l_trif_eq is TRUE.
-
JULES_VEGETATION::l_gleaf_fix
-
Switch for fixing a bug in the accumulation of g_leaf_phen_acc.
This bug occurs because veg2 is called on TRIFFID timesteps and veg1 is called on phenol timesteps, but veg1 did not previously accumulate g_leaf_phen_acc in the same way as veg2.
- TRUE
- veg1 accumulates g_leaf_phen_acc between calls to TRIFFID. This is important if triffid_period > phenol_period.
- FALSE
- veg1 does not accumulate g_leaf_phen_acc between calls to TRIFFID.
-
JULES_VEGETATION::l_bvoc_emis
-
Switch to enable calculation of BVOC emissions.
- TRUE
- BVOC emissions diagnostics will be calculated.
- FALSE
- BVOC emissions diagnostics will not be calculated.
-
JULES_VEGETATION::l_o3_damage
-
Switch for ozone damage.
- TRUE
Ozone damage is on.
- FALSE
- No effect.
-
JULES_VEGETATION::l_stem_resp_fix
-
Switch for bug fix for stem respiration to use balanced LAI to derive respiring stem mass. The switch is included for backwards compatability with existing configurations. Future updates should include this change.
- TRUE
- Respiring stem mass is derived allometrically.
- FALSE
- Respiring stem mass varies with seasonal LAI
-
JULES_VEGETATION::l_scale_resp_pm
-
Scale whole plant maintanence respiration by the soil moisture stress factor, instead of only scaling leaf respiration.
- TRUE
- Soil moisture stress reduces leaf, root, and stem maintanence respiration.
- FALSE
- Soil moisture stress only reduces leaf maintanence respiration.
-
JULES_VEGETATION::l_vegcan_soilfx
-
Switch for enhancement to canopy model to allow for conduction in the soil below the vegetative canopy, reducing coupling between the soil and the canopy.
- TRUE
- Allow for conduction in the soil.
- FALSE
- No effect.
-
JULES_VEGETATION::l_leaf_n_resp_fix
-
Switch for bug fix for leaf nitrogen content used in the calculation of plant maintenance respiration. The switch is included for backwards compatability with existing configurations. Runs with can_rad_mod =1, 4 or 5 are affected.
- TRUE
- Use correct forms for canopy-average leaf N content.
- FALSE
- No effect.
-
JULES_VEGETATION::l_landuse
-
Switch for using landuse change in conjunction with TRIFFID
Only used if l_triffid = TRUE.
- TRUE
- Land use change is implemented within TRIFFID. Litter fluxes are split between soil and wood product pools. Requires additional prognostics covering the product pools and the agricultural fraction from the previous TRIFFID call.
- FALSE
- All litter fluxes enter the soil
-
JULES_VEGETATION::l_recon
-
Switch for reconfiguring land fractions prior to TRIFFID call.
Only used if l_triffid = TRUE.
- TRUE
- For soil points (land points with no ice) set vegetation fractions to their minimum values and reduce bare soil fraction accordingly.
- FALSE
- Do not apply the minimum vegation fractions. This is useful when some points are 100% lake and urban, in which case reconfiguration leads to a total tile fraction of greater than 1.
-
JULES_VEGETATION::l_prescsow
-
Switch that determines how crop sowing dates are defined. Only used if ncpft > 0.
- TRUE
- Sowing dates prescribed in JULES_CROP_PROPS are used.
- FALSE
- Sowing dates are determined by the model.
-
JULES_VEGETATION::l_irrig_dmd
-
Switch controlling the implementation of irrigation demand code.
- TRUE
- Tiles are irrigated.
- FALSE
- No effect.
-
JULES_VEGETATION::l_irrig_limit
-
Switch controlling whether the amount of water used to irrigate tiles is limited.
- TRUE
Water for irrigation is taken first from the deep soil (groundwater) store, and then from the river storage when the deep soil store is exhausted. Tiles are irrigated up to the critical point if the necessary water is available. This option requires l_irrig_dmd = TRUE, l_top = TRUE, l_rivers = TRUE and rivers_type = trip.
Warning
The irrigation supply code in JULES is still in development, and is available in this release to support beta testing activities.
Users should ensure that results are as expected, and provide feedback where deficiencies are identified.
- FALSE
- Tiles will be irrigated to critical point from an unconstrained water supply.
-
JULES_VEGETATION::l_trif_crop
-
Switch controlling the treatment of agricultural PFTs. Where agricultural PFTs are defined by the crop_io parameter.
- TRUE
- In the non-agricultural area natural PFT competion is calculated by a call to a new version of the lotka routine and in each agricultural area agricultural-PFT competition is calculated by an additional call to the new version of the lotka routine. Crop and pasture areas are defined by the frac_agr and frac_past variables respectively. Additionally, to represent harvesting, a fraction of crop litter is added to the fast wood products pool instead of the soil carbon pools.
- FALSE
- Vegetation competition is calculated for natural and crop PFTs together, with natural PFTs excluded from the agricultural area that is defined by the frac_agr variable. Agricultural PFTs can also grow in natural areas where they are interpreted as natural grasses.
-
JULES_VEGETATION::irr_crop
Type: | integer |
Permitted: | 1 or 2 |
Default: | 1 |
- When to irrigate is determined from driving data according to Doell & Siebert (2002) method.
- When to irrigate is determined by maximum dvi across all tiles. Requires l_crop = T.
-
JULES_VEGETATION::can_model
Type: | integer |
Permitted: | 1-4 |
Default: | 4 |
Choice of canopy model for vegetation:
- No distinct canopy.
- Radiative canopy with no heat capacity.
- Radiative canopy with heat capacity. This option is deprecated, with 4 preferred.
- As 3 but with a representation of snow beneath the canopy. This option is preferred to 3.
Note
can_model = 1 does not mean that there is no vegetation canopy. It means that the surface is represented as a single entity, rather than having distinct surface and canopy levels for the purposes of radiative processes.
-
JULES_VEGETATION::can_rad_mod
Type: | integer |
Permitted: | 1-6 |
Default: | 4 |
Switch for treatment of canopy radiation.
- A single canopy layer for which radiation absorption is calculated using Beer’s law. Leaf-level photosynthesis is scaled to the canopy level using the ‘big leaf’ approach. Leaf nitrogen, photosynthetic capacity, i.e the Vcmax parameter, and leaf photosynthesis vary exponentially through the canopy with radiation.
- Multi-layer approach for radiation interception following the 2-stream approach of Sellers et al. (1992). This approach takes into account leaf angle distribution, zenith angle, and differentiates absorption of direct and diffuse radiation. Leaf-level photosynthesis is calculated using a vertically-varying light-limited rate, and constant Rubisco and export velocities, consistent with the assumption of constant leaf N through the canopy. Canopy photosynthesis and conductance are calculated as the sum over all layers.
- As 2, but photosynthesis calculated separately for sunlit and shaded leaves for the whole canopy (i.e. not at each layer). The definition of sunlit and shaded leaves is based on a threshold of absorbed radiation at each layer.
- This is a modification of option 2. Instead of constant leaf N through the canopy, it has a decline of leaf N with canopy height. Additionally includes inhibition of leaf respiration in the light.
- This is an improvement of option 4, including:
- Sunfleck penetration though the canopy.
- Division of sunlit and shaded leaves within each canopy level.
- A modified version of inhibition of leaf respiration in the light.
- This is an improvement of option 5, including an exponential decline of leaf N with canopy height proportional to LAI, following Beer’s law.
Note
can_rad_mod = 1 and 6 are recommended. can_rad_mod = 2 and 3 are deprecated and will be removed from the code at a future date.
Note
When using can_rad_mod = 4, 5 or 6 it is recommended to use driving data that contains direct and diffuse radiation separately rather than a constant diffuse fraction.
See also
Descriptions of options 1, 2 and 3 can be found in Jogireddy et al. (2006), and an application of option 4 can be found in Mercado et al. (2007). Options 1 to 5 are described in Clark et al (2011).
-
JULES_VEGETATION::ilayers
Type: | integer |
Permitted: | >= 0 |
Default: | 10 |
Number of layers for canopy radiation model. Only used for can_rad_mod = 2, 3, 4, 5 or 6.
These layers are used for the calculations of radiation interception and photosynthesis.
-
JULES_VEGETATION::frac_min
-
Minimum fraction that a PFT is allowed to cover if TRIFFID is used.
-
JULES_VEGETATION::frac_seed
-
Seed fraction for TRIFFID.
-
JULES_VEGETATION::pow
Type: | real |
Default: | 5.241e-4 |
Power in sigmodial function used to get competition coefficients.
See Hadley Centre Technical Note 24 Eq.3.
-
JULES_VEGETATION::l_inferno
-
Switch that determines whether interactive fires (INFERNO) is used. This allows for the diagnostic of burnt area,
burnt carbon and a variety of fire emissions.
- TRUE
- INFERNO is used to provide diagnostic fire variables
- FALSE
- INFERNO is not used.
-
JULES_VEGETATION::ignition_method
Type: | integer |
Permitted: | 1, 2, 3 |
Default: | 1 |
Switch to determine the type of ignition used (ubiquitous or prescribed with population and lightning)
- INFERNO uses ubiquitous (constant) ignitions, of 1.67 fires per km2 per s (1.5 from humans, 0.17 from lightning).
- INFERNO uses prescribed lightning ignitions, either from an ancillary or the UM.
Meanwhile humans are assumed to ignite 1.5 fires per km2 per s.
- INFERNO uses prescribed ignition using Population Density and Lightning Frequency (Cloud-to-Ground).
These must be provided as prescribed data to the JULES run.