MMF

The MMF soil erosion model requires the following land use specific model parameters (Table 11):

Table 16: MMF_table

Land use class	Plant height (PH)	Stem density (NV)	Stem diameter (D)	Canopy cover (CC)	Ground cover (GC)	No erosion	Tillage	Manning	No vege-tation
-99	1	2	3	4	5	6	7	8	9
1	10	0.5	0.4	0.8	0.65	0	0	0.2	0
2	0.5	4	0.2	0.5	0.5	0	0	0.1	0
3	0.2	20	0.15	0.3	0.35	0	1	0	1
…	…								…

Values for the plant height, stem density, stem diameter, canopy cover and ground cover can be found in Table 3 of Morgan & Duzant (2008), however, this table is mostly focused on British crop types and natural vegetation. Still, this table gives some suggestions for different vegetation types, which may help to define the model parameters for other geographical regions. The “no erosion” column is used to indicate with 0 (erosion) or 1 (no erosion) which land use types do not experience erosion, such as water and pavement. In case of no erosion, the sediment taken into transport will be set to 0. The “tillage” column indicates which land use classes apply tillage, i.e. 0 for no tillage and 1 for tillage. In case of tillage, the Manning’s roughness coefficient for soil will be obtained with the surface roughness parameter RFR (see below). The “Manning” column can be used to provide a Manning’s coefficient for irregular-spaced vegetation, commonly used for natural cover types (e.g. forest and shrubland). This column will be ignored in case it is set to 0, then the Manning’s roughness coefficient for vegetation will be determined with the stem density and stem diameter. When another value is provided, then the stem density and stem diameter will be ignored and the provided Manning’s coefficient will be considered. Manning’s coefficient values for different vegetation conditions can be obtained from Chow (1959). The “no vegetation” column is used to ignore the Manning’s roughness coefficient for vegetation. This can be useful in case of orchards, where the stem density is very low, which may result in unrealistic Manning’s roughness values.

Stem density, stem diameter and ground cover are commonly used for model calibration. Although literature values are available, these values are difficult to obtain for large study areas and may differ from agricultural field to agricultural field or from forest to forest.

The MMF soil erosion model may consider the changes of vegetation conditions in case of a sow-harvest cycle. In that case, the harvestFLAG should be set to 1. Another land use specific table (Table 12) should be provided, which gives the values for the period between harvest and sowing (commonly a fallow period):

Table 17: MMF_harvest

Land use class	Sowing	Harvest	Plant height (PH)	Stem density (NV)	Stem diameter (D)	Canopy cover (CC)	Ground cover (GC)	Tillage
-99	1	2	3	4	5	6	7	8
1	102	241	0.05	500	0.01	0.3	0.35	1
2	278	51	0	0	0	0	0	0
3	0	0	0	0	0	0	0	0
…			…

In the “sowing” and “harvest” column the days of the year (julian dates) should be provided of sowing and harvest, respectively. The other columns are similar to the MMF_table, with the difference that the values provided here (MMF_harvest) will be considered in the period between harvest and sowing and the MMF_table between sowing and harvest. When a land use class does not consider the sowing-harvest cycle (e.g. natural vegetation or orchards/vineyards), the dates should be set to 0.

Intensity of the erosive rain can be provided with the PrecInt model parameter. (Morgan and Duzant, 2008) propose 10 mm h-1 for temperate climates, 25 mm h-1 for tropical climates and 30 mm h-1 for strongly seasonal climates (e.g. Mediterranean, tropical monsoon). The intensity of the erosive precipitation will be based on the rainfall intensity obtained from the rainfall input when the infiltration excess surface runoff is used (i.e. Infil_excess = 1 in the INFILTRATION section of the config file).

The canopy cover values provided in the two tables, i.e. MMF_table and MMF_harvest, will be ignored when CanopyCoverLAIFlag is set to 1. In that case, the canopy cover will be obtained from the LAI determined by the vegetation module

The detachability of the soil by raindrop impact should be provided for each texture class. Based on laboratory experiments, (Quansah, 1982) proposed , and g J-1. Similarly, the detachability of the soil by runoff should be provided for each texture class, for which (Quansah, 1982) proposed , and g mm-1.

The particle diameter of the three textural classes should be provided, for which Morgan & Duzant (2008) proposes 2∙10-6 m for clay, 60∙10-6 m for silt and 200∙10-6 m for sand.

The Manning’s roughness coefficient for bare soil should be provided, for which a default value of 0.015 s m1/3 should be a reasonable first estimate.

The flow depth of bare soil, in-field flow depth and flow depth for transport capacity are used in the immediate deposition calculation. Values of, respectively, 0.005, 0.1 and 0.25 m are taken as default values.

The surface roughness parameter RFR is used for land use classes that apply tillage (see MMF_table and MMF_harvest). Morgan & Duzant (2008) provide a table (Table IV) with common values for RFR for different ploughing equipment.

The sediment and flow density are commonly set to 2650 and 1000 kg m-3, where the flow density may be slightly higher (e.g. 1100 kg m-3) for runoff on hillslopes (Abrahams et al., 2001).

The fluid viscosity is nominally set to 0.001 kg m-1 s-1, but often taken as 0.0015 to allow for the effects of the sediment in the flow ((Morgan and Duzant, 2008).

Table 18: Model parameters

Model parameter	Model variable	Unit	Range/default
Plant height	PH	m	0-50
Stem density	NV	stems m-2	0-10,000
Stem diameter	D	m	0-5
Canopy cover	CC	-	0-1
Ground cover	GC	-	0-1
No erosion		-	0 or 1
Tillage		-	0 or 1
Manning	n	s m-1/3	0.01-0.5
No vegetation		-	0 or 1
Sowing		day of the year	1-365
Harvest		day of the year	1-365
Intensity of the erosive rain	I	mm h-1	10-50
Detachability of the soil by raindrop impact	Kc, Kz, Ks	g J-1	0.1, 0.5, 0.3
Detachability of the soil by runoff	DRc, DRz, DRs	g mm-1	1.0, 1.6, 1.5
Particle diameter	δc, δz, δs,	m	2 ∙ 10-6, 60 ∙ 10-6, 200 ∙ 10-6
Bare soil Manning’s roughness coefficient	nsoil	s m-1/3	0.015
Flow depth bare soil	dbare	m	0.005
Flow depth in field	dfield	m	0.1
Flow depth transport capacity	dTC	m	0.25
Surface roughness parameter for tillage	RFR	cm m-1	6-48
Sediment density	ρs	kg m-3	2650
Flow density	ρ	kg m-3	1100
Fluid viscosity	η	kg m-1 s-1	0.0015