6.22. pft_params.nml
¶
This file can contain 2 namelists called JULES_PFTPARM
and JULES_PFTPARM_CABLE
that set time and space-invariant parameters for plant functional types for the JULES and CABLE land surface models respectively.
Note
If the crop model is on (i.e. ncpft
> 0), the order of PFTs must be natural PFTs followed by crop PFTs.
6.22.1. JULES_PFTPARM
namelist members¶
This namelist reads the values of parameters for each of the plant functional types (PFTs) if the JULES land surface model is being used. These parameters are a function of PFT only. Parameters that also vary with time and location can be prescribed in prescribed_data.nml. Parameters that are only required if the dynamic vegetation (TRIFFID) or phenology sections are requested are read separately in triffid_params.nml. Every member must be given a value for every run.
HCTN24 and 30 refer to Hadley Centre technical notes 24 and 30, available from the Met Office Library. For ease the direct links to these documents are:
- HCTN24 “Description of the “TRIFFID” Dynamic Global Vegetation Model”
- HCTN30 “MOSES 2.2 technical documentation”
-
JULES_PFTPARM::
canht_ft_io
¶ Type: real(npft) Default: None The height of each PFT (m), also known as the canopy height.
The value read here is only used if TRIFFID is not active (
l_triffid
= FALSE).Note
If TRIFFID is active, canopy height is a prognostic variable and its initial value is read in initial_conditions.nml.
-
JULES_PFTPARM::
lai_io
¶ Type: real(npft) Default: None The leaf area index (LAI) of each PFT.
The value read here is only used if neither phenology nor TRIFFID is active (
l_phenol
= FALSE andl_triffid
= FALSE).Note
If phenology is active, LAI is a prognostic variable and its initial value is read in initial_conditions.nml. When TRIFFID is active but phenology is not active (not recommended), LAI is calculated from the canopy height (meaning that the seasonal cycle of LAI will not be correctly represented).
-
JULES_PFTPARM::
c3_io
¶ Type: integer(npft) Default: None Flag indicating whether PFT is C3 type.
- Not C3 (i.e. C4).
- C3.
-
JULES_PFTPARM::
orient_io
¶ Type: integer(npft) Default: None Flag indicating leaf angle distribution.
- Spherical.
- Horizontal.
-
JULES_PFTPARM::
can_struct_a_io
¶ Type: real(npft) Default: None Canopy structure factor (dimensionless). can_struct_a_io=1.0 indicates a structurally homogeneous canopy. Corresponds to the structure factor Zeta in Pinty et al 2006 except assumed not to vary with zenith angle i.e. b=0. The canopy structure factor has no effect if
can_rad_mod
= 1.
-
JULES_PFTPARM::
a_wl_io
¶ Type: real(npft) Default: None Allometric coefficient relating the target woody biomass to the leaf area index (kg carbon m-2) (Clark et al., 2011; Table 7)
-
JULES_PFTPARM::
a_ws_io
¶ Type: real(npft) Default: None Woody biomass as a multiple of live stem biomass (Clark et al., 2011; Table 7).
-
JULES_PFTPARM::
albsnc_max_io
¶ Type: real(npft) Default: None Snow-covered albedo for large leaf area index.
Only used if
l_snow_albedo
= FALSE. See HCTN30 Eq.2.
-
JULES_PFTPARM::
albsnc_min_io
¶ Type: real(npft) Default: None Snow-covered albedo for zero leaf area index.
Only used if
l_snow_albedo
= FALSE. See HCTN30 Eq.2.
-
JULES_PFTPARM::
albsnf_max_io
¶ Type: real(npft) Default: None Snow-free albedo for large LAI.
Only used if
l_spec_albedo
= FALSE. See HCTN30 Eq.1.
-
JULES_PFTPARM::
albsnf_maxu_io
¶ Type: real(npft) Default: None Upper bound for the snow-free albedo for large LAI, when scaled to match input obs.
Only used if
l_spec_albedo
= FALSE andl_albedo_obs
= TRUE.
-
JULES_PFTPARM::
albsnf_maxl_io
¶ Type: real(npft) Default: None Lower bound for the snow-free albedo for large LAI, when scaled to match input obs.
Only used if
l_spec_albedo
= FALSE andl_albedo_obs
= TRUE.
-
JULES_PFTPARM::
alpha_io
¶ Type: real(npft) Default: None Quantum efficiency of photosynthesis (mol CO2 per mol PAR photons).
-
JULES_PFTPARM::
alnir_io
¶ Type: real(npft) Default: None Leaf reflection coefficient for NIR. See HCTN30 Table 3.
Always used unless
can_rad_mod
= 1 andl_spec_albedo
= FALSE.
-
JULES_PFTPARM::
alniru_io
¶ Type: real(npft) Default: None Upper limit for the leaf reflection coefficient for NIR, when
l_albedo_obs
= TRUE and whenalnir_io
is used.
-
JULES_PFTPARM::
alnirl_io
¶ Type: real(npft) Default: None Lower limit for the leaf reflection coefficient for NIR, when
l_albedo_obs
= TRUE and whenalnir_io
is used.
-
JULES_PFTPARM::
alpar_io
¶ Type: real(npft) Default: None Leaf reflection coefficient for VIS (photosyntehtically active radiation). See HCTN30 Table 3.
Always used unless
can_rad_mod
= 1 andl_spec_albedo
= FALSE.
-
JULES_PFTPARM::
alparu_io
¶ Type: real(npft) Default: None Upper limit for the leaf reflection coefficient for VIS, when
l_albedo_obs
= TRUE and whenalpar_io
is used.
-
JULES_PFTPARM::
alparl_io
¶ Type: real(npft) Default: None Lower limit for the leaf reflection coefficient for VIS, when
l_albedo_obs
= TRUE and whenalpar_io
is used.
-
JULES_PFTPARM::
b_wl_io
¶ Type: real(npft) Default: None Allometric exponent relating the target woody biomass to the leaf area index. This is 5/3 in HCTN24 Eq.8. See also Clark et al. (2011, Table 7).
-
JULES_PFTPARM::
catch0_io
¶ Type: real(npft) Default: None Minimum canopy capacity (kg m-2).
This is the minimum amount of water that can be held on the canopy. See HCTN30 p7.
-
JULES_PFTPARM::
dcatch_dlai_io
¶ Type: real(npft) Default: None Rate of change of canopy capacity with LAI (kg m-2).
Canopy capacity is calculated as
catch0 + dcatch_dlai*lai
. See HCTN30 p7.
-
JULES_PFTPARM::
dgl_dm_io
¶ Type: real(npft) Default: None Rate of change of leaf turnover rate with moisture availability.
-
JULES_PFTPARM::
dgl_dt_io
¶ Type: real(npft) Default: None Rate of change of leaf turnover rate with temperature (K-1).
This is 9 in HCTN24 Eq.10.
-
JULES_PFTPARM::
dqcrit_io
¶ Type: real(npft) Default: None Critical humidity deficit (kg H2O per kg air).
Only used with the Jacobs model of stomatal conductance (
stomata_model
= 1).
-
JULES_PFTPARM::
dz0v_dh_io
¶ Type: real(npft) Default: None Rate of change of vegetation roughness length for momentum with height.
Roughness length is calculated as
dz0v_dh * canht_ft
. See HCTN30 p5.Used if logical
l_spec_veg_z0
is set to .false.
-
JULES_PFTPARM::
z0v_io
¶ Type: real(npft) Default: None Specified values for the vegetation roughness length for momentum.
Used if logical
l_spec_veg_z0
is set to .true.
-
JULES_PFTPARM::
eta_sl_io
¶ Type: real(npft) Default: None Live stemwood coefficient (kg C/m/(m2 leaf)) (Clark et al., 2011; Table 7).
-
JULES_PFTPARM::
fd_io
¶ Type: real(npft) Default: None Scale factor for dark respiration. See HCTN 24 Eq. 56.
-
JULES_PFTPARM::
fsmc_of_io
¶ Type: real(npft) Default: None Moisture availability below which leaves are dropped.
-
JULES_PFTPARM::
f0_io
¶ Type: real(npft) Default: None CI / CA
forDQ = 0
. See HCTN 24 Eq. 32.Only used with the Jacobs model of stomatal conductance (
stomata_model
= 1).
-
JULES_PFTPARM::
g1_stomata_io
¶ Type: real(npft) Default: None Parameter g1 for the Medlyn et al. (2011) model of stomatal conductance (kPa0.5) - this is the sensitivity of the stomatal conductance to the assimilation rate. See Eqn.11 in Medlyn et al. (2012), https://doi.org/10.1111/j.1365-2486.2012.02790.x.
Only used with the Medlyn model of stomatal conductance (
stomata_model
= 2).
-
JULES_PFTPARM::
g_leaf_0_io
¶ Type: real(npft) Default: None Minimum turnover rate for leaves (/360days).
-
JULES_PFTPARM::
glmin_io
¶ Type: real(npft) Default: None Minimum leaf conductance for H2O (m s-1).
-
JULES_PFTPARM::
infil_f_io
¶ Type: real(npft) Default: None Infiltration enhancement factor.
The maximum infiltration rate defined by the soil parameters for the whole gridbox may be modified for each PFT to account for tile-dependent factors, such as macro-pores related to vegetation roots.
See HCTN30 p14 for full details.
-
JULES_PFTPARM::
hw_sw_io
¶ Type: real(npft) Default: None Ratio of N stem to N heartwood (kgN/kgN) from the TRY database.
Only used if
l_trait_phys
= T.
-
JULES_PFTPARM::
kext_io
¶ Type: real(npft) Default: None Light extinction coefficient - used with Beer’s Law for light absorption through tile canopies. See HCTN30 Eq.3.
-
JULES_PFTPARM::
kpar_io
¶ Type: real(npft) Default: None PAR Extinction coefficient (m2 leaf / m2 ground).
-
JULES_PFTPARM::
lai_alb_lim_io
¶ Type: real(npft) Default: None Minimum LAI permitted in calculation of the albedo in snow-free conditions.
-
JULES_PFTPARM::
neff_io
¶ Type: real(npft) Default: None Scale factor relating Vcmax with leaf nitrogen concentration. See HCTN 24 Eq. 51.
Only used if
l_trait_phys
= F.
-
JULES_PFTPARM::
nl0_io
¶ Type: real(npft) Default: None Top leaf nitrogen concentration (kg N/kg C).
Only used if
l_trait_phys
= F.
-
JULES_PFTPARM::
nr_nl_io
¶ Type: real(npft) Default: None Ratio of root nitrogen concentration to leaf nitrogen concentration.
-
JULES_PFTPARM::
nr_io
¶ Type: real(npft) Default: None Root nitrogen concentration (kgN/kgC). Only used if
l_trait_phys
= T.
-
JULES_PFTPARM::
ns_nl_io
¶ Type: real(npft) Default: None Ratio of stem nitrogen concentration to leaf nitrogen concentration.
-
JULES_PFTPARM::
nsw_io
¶ Type: real(npft) Default: None Stemwood nitrogen concentration (kgN/kgC). Only used if
l_trait_phys
= T.
-
JULES_PFTPARM::
hw_sw_io
Type: real(npft) Default: None Ratio of Heartwood to Stemwood Nitrogen Concentration (typically 0.5) Only used if
l_trait_phys
= T.
-
JULES_PFTPARM::
omega_io
¶ Type: real(npft) Default: None Leaf scattering coefficient for PAR.
Always used unless
can_rad_mod
= 1 andl_spec_albedo
= FALSE.
-
JULES_PFTPARM::
omegau_io
¶ Type: real(npft) Default: None Upper limit for the leaf scattering coefficient for PAR, when
l_albedo_obs
= TRUE and whenomega_io
is used.
-
JULES_PFTPARM::
omegal_io
¶ Type: real(npft) Default: None Lower limit for the leaf scattering coefficient for PAR, when
l_albedo_obs
= TRUE and whenomega_io
is used.
-
JULES_PFTPARM::
omnir_io
¶ Type: real(npft) Default: None Leaf scattering coefficient for NIR.
Always used unless
can_rad_mod
= 1 andl_spec_albedo
= FALSE.
-
JULES_PFTPARM::
omniru_io
¶ Type: real(npft) Default: None Upper limit for the leaf scattering coefficient for NIR, when
l_albedo_obs
= TRUE and whenomnir_io
is used.
-
JULES_PFTPARM::
omnirl_io
¶ Type: real(npft) Default: None Lower limit for the leaf scattering coefficient for NIR, when
l_albedo_obs
= TRUE and whenomnir_io
is used.
-
JULES_PFTPARM::
r_grow_io
¶ Type: real(npft) Default: None Growth respiration fraction.
-
JULES_PFTPARM::
fsmc_mod_io
¶ Type: integer(npft) Default: None Switch for method of weighting the contribution that different soil layers make to the soil moisture availability factor fsmc.
- (recommended) Calculate fsmc in each soil layer and take a weighted average, using the fraction of roots in each layer as weights. Root distribution e-folding depth is given by
rootd_ft_io
. - Calculate fsmc using average properties for the root zone. Depth of root zone is given by
rootd_ft_io
. This is not currently allowed if layered soil C (l_layeredc
= TRUE) and the RothC model are selected (soil_bgc_model
= 2) because of unplanned effects on litter inputs.
- (recommended) Calculate fsmc in each soil layer and take a weighted average, using the fraction of roots in each layer as weights. Root distribution e-folding depth is given by
-
JULES_PFTPARM::
psi_open_io
¶ Type: real(npft) Default: None Soil potential above which the soil moisture stress factor on vegetation (fsmc) is one. Unit: Pa. Allowed range: must be negative. Only used if
l_use_pft_psi
= T.
-
JULES_PFTPARM::
psi_close_io
¶ Type: real(npft) Default: None Soil potential below which the soil moisture stress factor on vegetation (fsmc) is zero. Unit: Pa. Allowed range: must be negative. Only used if
l_use_pft_psi
= T.
-
JULES_PFTPARM::
rootd_ft_io
¶ Type: real(npft) Default: None Parameter determining the root depth (m).
If
fsmc_mod_io
= 0, an exponential root distribution with depth is assumed, with e-folding depthrootd_ft
(see HCTN30 Eq.32). Note that this means that generally some of the roots exist at depths greater thanrootd_ft
. Iffsmc_mod_io
= 1,rootd_ft
is the total depth of the root zone.
-
JULES_PFTPARM::
fsmc_p0_io
¶ Type: real(npft) Default: None Pft-dependent parameter governing the threshold at which the plant starts to experience water stress due to lack of water in the soil. Only used if
l_use_pft_psi
= F. The volumetric soil moisture content (m3 water per m3 soil) at which the plant starts to become water stressed issm_wilt+(sm_crit-sm_wilt)*(1-fsmc_p0)
(seeJULES_SOIL_PROPS
for a description ofsm_wilt
andsm_crit
).
-
JULES_PFTPARM::
sigl_io
¶ Type: real(npft) Default: None Specific density of leaf carbon (kg C/m2 leaf) (Clark et al., 2011; Table 7).
Only used if
l_trait_phys
= F.
-
JULES_PFTPARM::
tleaf_of_io
¶ Type: real(npft) Default: None Temperature below which leaves are dropped (K).
-
JULES_PFTPARM::
tlow_io
¶ Type: real(npft) Default: None Lower temperature parameter for photosynthesis (deg C), for the Collatz model of leaf photosynthesis.
Always used for C4 plants. Only used for C3 plants with the Collatz model of leaf photosynthesis (
photo_model
= 1).
-
JULES_PFTPARM::
tupp_io
¶ Type: real(npft) Default: None Upper temperature parameter for photosynthesis (deg C), for the Collatz model of leaf photosynthesis.
Always used for C4 plants. Only used for C3 plants with the Collatz model of leaf photosynthesis (
photo_model
= 1).
-
JULES_PFTPARM::
emis_pft_io
¶ Type: real(npft) Default: None Surface emissivity of vegetated surfaces.
-
JULES_PFTPARM::
z0hm_pft_io
¶ Type: real(npft) Default: None Ratio of the roughness length for heat to the roughness length for momentum.
This is generally assumed to be 0.1. See HCTN30 p6. Note that this is the ratio of the roughness length for heat to that for momentum. It does not alter the roughness length for momentum, which is calculated using
canht_ft_io
anddz0v_dh_io
.
-
JULES_PFTPARM::
z0hm_classic_pft_io
¶ Type: real(npft) Default: None Ratio of the roughness length for heat to the roughness length for momentum for the CLASSIC aerosol scheme only.
Note
This makes no difference to the model when running standalone, and is only required to keep the standalone and UM interfaces consistent.
-
JULES_PFTPARM::
fl_o3_ct_io
¶ Type: real(npft) Default: None Critical flux of O3 to vegetation (nmol m-2 s-1).
-
JULES_PFTPARM::
dfp_dcuo_io
¶ Type: real(npft) Default: None Plant type specific O3 sensitivity parameter (nmol-1 m2 s).
-
JULES_PFTPARM::
ief_io
¶ Type: real(npft) Default: None Isoprene Emission Factor (μg g-1 h-1).
-
JULES_PFTPARM::
tef_io
¶ Type: real(npft) Default: None Monoterpene Emission Factor (μg g-1 h-1).
-
JULES_PFTPARM::
mef_io
¶ Type: real(npft) Default: None Methanol Emission Factor (μg g-1 h-1).
-
JULES_PFTPARM::
aef_io
¶ Type: real(npft) Default: None Acetone Emission Factor (μg g-1 h-1).
-
JULES_PFTPARM::
ci_st_io
¶ Tybe: real(npft) Default: None Leaf-internal CO2concentration at standard conditions (Pa),
Note
Standard conditions are: T = 303.15K, p = 1013.25 hPa, atmospheric CO2 = 370 ppmv, PAR = 1000 μmol m-2 s-1.
-
JULES_PFTPARM::
gpp_st_io
¶ Tybe: real(npft) Default: None Gross primary production (GPP) at standard conditions (kgC m-2 s-1),
Note
Standard conditions are: T = 303.15K, p = 1013.25 hPa, atmospheric CO2 = 370 ppmv, PAR = 1000 μmol m-2 s-1.
-
JULES_PFTPARM::
nmass_io
¶ Type: real(npft) Default: None Top leaf nitrogen content per unit mass (kgN kgLeaf-1).
Only used if
l_trait_phys
= T.
-
JULES_PFTPARM::
lma_io
¶ Type: real(npft) Default: None Leaf mass per unit area (kgLeaf m-2).
Only used if
l_trait_phys
= T.
-
JULES_PFTPARM::
vint_io
¶ Type: real(npft) Default: None There is a linear relationship between Vcmax and Narea. Previously Vcmax was calculated as the product of nl0 and neff.
This is now replaced by a linear regression based on data reported in Kattge et al. 2009. Vint is the y-intercept, vsl is the slope.
Units: μmol CO2 m-2 s-1.
Only used if
l_trait_phys
= T.
-
JULES_PFTPARM::
vsl_io
¶ Type: real(npft) Default: None Slope in the linear regression between Vcmax and Narea.
Units: μmol CO2 gN-1 s-1.
Only used if
l_trait_phys
= T.
-
JULES_PFTPARM::
kn_io
¶ Type: real(npft) Default: None. Parameter for decay of nitrogen through the canopy, as a function of layers. Only used if
can_rad_mod
= 4 or 5.
-
JULES_PFTPARM::
knl_io
¶ Type: real(npft) Default: None. Parameter for decay of nitrogen through the canopy, as a function of LAI. Only used if
can_rad_mod
= 6.
-
JULES_PFTPARM::
q10_leaf_io
¶ Type: real(npft) Default: None. Q10 factor for plant respiration.
See Cox et al. (1999) Eq. 66.
Note
Was previously a single parameter but now can have PFT-dependent values.
-
JULES_PFTPARM::
fef_co2_io
¶ Type: real(npft) Default: None Fire CO2 Emission Factor (g kg-1).
-
JULES_PFTPARM::
fef_co_io
¶ Type: real(npft) Default: None Fire CO Emission Factor (g kg-1).
-
JULES_PFTPARM::
fef_ch4_io
¶ Type: real(npft) Default: None Fire CH4 Emission Factor (g kg-1).
-
JULES_PFTPARM::
fef_nox_io
¶ Type: real(npft) Default: None Fire NOx Emission Factor (g kg-1).
-
JULES_PFTPARM::
fef_so2_io
¶ Type: real(npft) Default: None Fire SO2 Emission Factor (g kg-1).
-
JULES_PFTPARM::
fef_oc_io
¶ Type: real(npft) Default: None Fire OC Emission Factor (g kg-1).
-
JULES_PFTPARM::
fef_bc_io
¶ Type: real(npft) Default: None Fire BC Emission Factor (g kg-1).
-
JULES_PFTPARM::
ccleaf_min_io
¶ Type: real(npft) Default: None Leaf minimum combustion completeness.
-
JULES_PFTPARM::
ccleaf_max_io
¶ Type: real(npft) Default: None Leaf maximum combustion completeness.
-
JULES_PFTPARM::
ccwood_min_io
¶ Type: real(npft) Default: None Wood minimum combustion completeness.
-
JULES_PFTPARM::
ccwood_max_io
¶ Type: real(npft) Default: None Wood maximum combustion completeness.
-
JULES_PFTPARM::
avg_ba_io
¶ Type: real(npft) Default: None Average PFT Burnt Area per fire (m2).
-
JULES_PFTPARM::
fire_mort_io
¶ Type: real(npft) Default: None Scaling factor for vegetation mortality caused by fire (from INFERNO burned area). Can be varied between 0.0 (no morality) and 1.0 (100% mortality) for each PFT.
See also
References:
- Clark et al., 2011, The Joint UK Land Environment Simulator (JULES), model description – Part 2: Carbon fluxes and vegetation dynamics, Geosci. Model Dev., 4, 701-722, https://doi.org/10.5194/gmd-4-701-2011
- Pinty, B., T. Lavergne, R. E. Dickinson, J.-L. Widlowski, N. Gobron, and M. M. Verstraete (2006), Simplifying the interaction of land surfaces with radiation for relating remote sensing products to climate models, J. Geophys. Res., 111, D02116, https://doi.org/10.1029/2005JD005952.
Only used with the Farquhar model of leaf photosynthesis (photo_model
= 2). A value is required for each PFT, but only those for C3 plants are used (since only C3 plants use the Farquhar model). Below, Jmax is the potential rate of electron transport, and Vcmax is the maximum rate of carboxylation of Rubisco.
-
JULES_PFTPARM::
act_jmax_io
¶ Type: real(npft) Default: None Activation energy for temperature response of Jmax (J mol-1).
-
JULES_PFTPARM::
act_vcmax_io
¶ Type: real(npft) Default: None Activation energy for temperature response of Vcmax (J mol-1).
-
JULES_PFTPARM::
alpha_elec_io
¶ Type: real(npft) Default: None Quantum yield of electron transport (mol electrons [mol-1 PAR photons]).
-
JULES_PFTPARM::
deact_jmax_io
¶ Type: real(npft) Default: None Deactivation energy for temperature response of Jmax (J mol-1). This describes the rate of decrease above the optimum temperature.
-
JULES_PFTPARM::
deact_vcmax_io
¶ Type: real(npft) Default: None Deactivation energy for temperature response of Vcmax (J mol-1). This describes the rate of decrease above the optimum temperature.
-
JULES_PFTPARM::
jv25_ratio_io
¶ Type: real(npft) Default: None Ratio of Jmax to Vcmax at 25 deg C (mol electrons [mol-1 CO2]).
Note
If thermal adaptation or acclimation of photosynthesis is selected (
photo_acclim_model
= 1 or 2) together withphoto_jv_model
=2 (Jmax/Vcmax calculated assuming constant total nitrogen allocation)), this value is used along with parametersn_alloc_jmax
andn_alloc_vcmax
to calculate the final value of Jmax/Vcmax.
Only used if thermal adapatation or acclimation of photosynthetic capacity is NOT modelled (photo_acclim_model
= 0). A value is required for each PFT, but only those for C3 plants are used (since only C3 plants use the Farquhar model).
-
JULES_PFTPARM::
ds_jmax_io
¶ Type: real(npft) Default: None Entropy factor for temperature reponse of Jmax (J mol-1 K-1).
-
JULES_PFTPARM::
ds_vcmax_io
¶ Type: real(npft) Default: None Entropy factor for temperature reponse of Vcmax (J mol-1 K-1).
6.22.2. JULES_PFTPARM_CABLE
namelist members¶
This namelist reads the values of parameters for each of the plant functional types (PFTs) if the CABLE land surface model is being used. These parameters are a function of PFT only. Every member must be given a value for every run. CABLE uses the same parameters for veg and non-veg surface types, unlike JULES, and therefore its arrays are of dimension (npft + nnvg).
-
JULES_PFTPARM_CABLE::
a1gs_io
¶ Type: real(npft + nnvg) Default: MDI Represents the sensitivity of stomatal conductance to the assimilation rate (unitless).
-
JULES_PFTPARM_CABLE::
alpha_io
¶ Type: real(npft + nnvg) Default: MDI Initial slope of J-Q response curve. Units: mol (electrons) mol-1 (photons) (C3) mol (CO2) mol-1 (photons) (C4)
-
JULES_PFTPARM_CABLE::
canst1_io
¶ Type: real(npft + nnvg) Default: MDI Maximum intercepted water by canopy. (mm LAI-1)
-
JULES_PFTPARM_CABLE::
cfrd_io
¶ Type: real(npft + nnvg) Default: MDI Ratio of day respiration to vcmax
-
JULES_PFTPARM_CABLE::
clitt_io
¶ Type: real(npft + nnvg) Default: MDI Leaf litter (alters resistance to soil evaporation) (tC ha-1)
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JULES_PFTPARM_CABLE::
conkc0_io
¶ Type: real(npft + nnvg) Default: MDI Michaelis-menton constant for carboxylase (bar)
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JULES_PFTPARM_CABLE::
conko0_io
¶ Type: real(npft + nnvg) Default: MDI Michaelis-menton constant for oxygenase (bar)
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JULES_PFTPARM_CABLE::
convex_io
¶ Type: real(npft + nnvg) Default: MDI Convexity of J-Q response curve (unitless).
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JULES_PFTPARM_CABLE::
cplant1_io
¶ Type: real(npft + nnvg) Default: MDI Plant carbon in 1st vegetation carbon store (g C m-2)
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JULES_PFTPARM_CABLE::
cplant2_io
¶ Type: real(npft + nnvg) Default: MDI Plant carbon in 2nd vegetation carbon store (g C m-2)
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JULES_PFTPARM_CABLE::
cplant3_io
¶ Type: real(npft + nnvg) Default: MDI Plant carbon in 3rd vegetation carbon store (g C m-2)
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JULES_PFTPARM_CABLE::
csoil1_io
¶ Type: real(npft + nnvg) Default: MDI Soil carbon in 1st soil carbon store (g C m-2)
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JULES_PFTPARM_CABLE::
csoil2_io
¶ Type: real(npft + nnvg) Default: MDI Soil carbon in 2nd soil carbon store (g C m-2)
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JULES_PFTPARM_CABLE::
d0gs_io
¶ Type: real(npft + nnvg) Default: MDI d0 in stomatal conductance model (kPa)
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JULES_PFTPARM_CABLE::
ejmax_io
¶ Type: real(npft + nnvg) Default: MDI Maximum potential electron transport rate top leaf, currently double the assigned value of vcmax. (mol m-2 s-1)
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JULES_PFTPARM_CABLE::
ekc_io
¶ Type: real(npft + nnvg) Default: MDI Activation energy for carboxylase (J mol-1)
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JULES_PFTPARM_CABLE::
eko_io
¶ Type: real(npft + nnvg) Default: MDI Activation energy for oxygenase (J mol-1)
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JULES_PFTPARM_CABLE::
extkn_io
¶ Type: real(npft + nnvg) Default: MDI Extinction coefficient for vertical profile of N.
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JULES_PFTPARM_CABLE::
frac4_io
¶ Type: real(npft + nnvg) Default: MDI Fraction of c4 plants
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JULES_PFTPARM_CABLE::
froot1_io
¶ Type: real(npft + nnvg) Default: MDI Fraction of root in 1st soil layer.
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JULES_PFTPARM_CABLE::
froot2_io
¶ Type: real(npft + nnvg) Default: MDI Fraction of root in 2nd soil layer.
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JULES_PFTPARM_CABLE::
froot3_io
¶ Type: real(npft + nnvg) Default: MDI Fraction of root in 3rd soil layer.
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JULES_PFTPARM_CABLE::
froot4_io
¶ Type: real(npft + nnvg) Default: MDI Fraction of root in 4th soil layer.
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JULES_PFTPARM_CABLE::
froot5_io
¶ Type: real(npft + nnvg) Default: MDI Fraction of root in 5th soil layer.
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JULES_PFTPARM_CABLE::
froot6_io
¶ Type: real(npft + nnvg) Default: MDI Fraction of root in 6th soil layer.
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JULES_PFTPARM_CABLE::
g0_io
¶ Type: real(npft + nnvg) Default: MDI Residual stomatal conductance as net assimilation rate reaches zero (mol m-2 s-1)
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JULES_PFTPARM_CABLE::
g1_io
¶ Type: real(npft + nnvg) Default: MDI Sensitivity of stomatal conductance to the assimilation rate (kPa).
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JULES_PFTPARM_CABLE::
gswmin_io
¶ Type: real(npft + nnvg) Default: MDI Minimal stomatal conductance (mol m-2 s-1)
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JULES_PFTPARM_CABLE::
hc_io
¶ Type: real(npft + nnvg) Default: MDI Height of canopy (m)
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JULES_PFTPARM_CABLE::
length_io
¶ Type: real(npft + nnvg) Default: MDI Leaf length (m)
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JULES_PFTPARM_CABLE::
ratecp1_io
¶ Type: real(npft + nnvg) Default: MDI Plant carbon pool rate constant in 1st vegetation carbon store (year-1).
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JULES_PFTPARM_CABLE::
ratecp2_io
¶ Type: real(npft + nnvg) Default: MDI Plant carbon pool rate constant in 2nd vegetation carbon store (year-1).
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JULES_PFTPARM_CABLE::
ratecp3_io
¶ Type: real(npft + nnvg) Default: MDI Plant carbon pool rate constant in 3rd vegetation carbon store (year-1).
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JULES_PFTPARM_CABLE::
ratecs1_io
¶ Type: real(npft + nnvg) Default: MDI Soil carbon pool rate constant in 1st soil carbon store (year-1).
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JULES_PFTPARM_CABLE::
ratecs2_io
¶ Type: real(npft + nnvg) Default: MDI Soil carbon pool rate constant in 2nd soil carbon store (year-1).
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JULES_PFTPARM_CABLE::
refl1_io
¶ Type: real(npft + nnvg) Default: MDI Leaf reflectance in 1st radiation band.
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JULES_PFTPARM_CABLE::
refl2_io
¶ Type: real(npft + nnvg) Default: MDI Leaf reflectance in 2nd radiation band.
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JULES_PFTPARM_CABLE::
refl3_io
¶ Type: real(npft + nnvg) Default: MDI Leaf reflectance in 3rd radiation band.
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JULES_PFTPARM_CABLE::
rp20_io
¶ Type: real(npft + nnvg) Default: MDI Plant respiration scaler
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JULES_PFTPARM_CABLE::
rpcoef_io
¶ Type: real(npft + nnvg) Default: MDI Temperature coefficient for non-leaf plant respiration (C-1)
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JULES_PFTPARM_CABLE::
rs20_io
¶ Type: real(npft + nnvg) Default: MDI Soil respiration at 20 deg C
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JULES_PFTPARM_CABLE::
shelrb_io
¶ Type: real(npft + nnvg) Default: MDI Sheltering factor
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JULES_PFTPARM_CABLE::
taul1_io
¶ Type: real(npft + nnvg) Default: MDI Leaf transmittance in 1st radiation band
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JULES_PFTPARM_CABLE::
taul2_io
¶ Type: real(npft + nnvg) Default: MDI Leaf transmittance in 2nd radiation band
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JULES_PFTPARM_CABLE::
taul3_io
¶ Type: real(npft + nnvg) Default: MDI Leaf transmittance in 3rd radiation band
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JULES_PFTPARM_CABLE::
tmaxvj_io
¶ Type: real(npft + nnvg) Default: MDI Maximum temperature of the start of photosynthesis (deg C)
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JULES_PFTPARM_CABLE::
tminvj_io
¶ Type: real(npft + nnvg) Default: MDI Minimum temperature of the start of photosynthesis (deg C)
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JULES_PFTPARM_CABLE::
vbeta_io
¶ Type: real(npft + nnvg) Default: MDI Stomatal sensitivity to soil water.
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JULES_PFTPARM_CABLE::
vcmax_io
¶ Type: real(npft + nnvg) Default: MDI Maximum RuBP carboxylation rate top leaf. (mol m-2 s-1)
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JULES_PFTPARM_CABLE::
vegcf_io
¶ Type: real(npft + nnvg) Default: MDI Scalar on soil respiration (place-holder scheme)
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JULES_PFTPARM_CABLE::
wai_io
¶ Type: real(npft + nnvg) Default: MDI Wood area index (stem + branches + twigs) (not currently used in any calculations)
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JULES_PFTPARM_CABLE::
width_io
¶ Type: real(npft + nnvg) Default: MDI Leaf width (m)
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JULES_PFTPARM_CABLE::
xalbnir_io
¶ Type: real(npft + nnvg) Default: MDI Not currently used in any calculations.
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JULES_PFTPARM_CABLE::
xfang_io
¶ Type: real(npft + nnvg) Default: MDI Leaf angle parameter
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JULES_PFTPARM_CABLE::
zr_io
¶ Type: real(npft + nnvg) Default: MDI Maximum rooting depth (cm)