AquaCrop Simulation of Winter Wheat under Different N Management Practices
Abstract
:1. Introduction
2. Materials and Methods
2.1. Field Experiments and Data
2.2. Soil Moisture Measurement Network
2.3. AquaCrop Model Description
2.4. Simulation Procedure
- (i)
- The evaluation aimed at the effectiveness of AquaCrop to simulate the soil water content evolution and crop yield in different areas of an experimental field under different treatments. Two soil water content profiles (up to 1 m depth) in the 2015–2016 growing season and four profiles in the 2016–2017 growing season were used (Figure 3). Table 2 present the conservative and the nonconservative parameters used for the simulations during the two growing seasons. The model was adjusted to crop yield (kg/ha) as measured in plot samples. Measurement of soil water content is a prerequisite for establishing a reliable water balance at the field scale.
- (ii)
- AquaCrop was evaluated to estimate the wheat yield under different treatments. The simulation was a two-step procedure: (a) simulations at field positions with 30 cm soil moisture sensors (blocks/repetitions 2 and 3) were used to determine soil water content evolution, yield, and average fertility per zone and treatment (Calibration of the model); (b) using these fertility levels and local soil data, crop production was estimated in other parts of the field with available yield data (blocks/repetitions 1 and 4) under different N treatments. The simulated yields were compared to the field yields (Validation of the model). For the simulation, we used the default in the AquaCrop wheat.cro file (Valenzano).
3. Results
3.1. Meteorological and Soil Conditions
3.2. Simulation: Model Calibration and Validation
4. Discussion
4.1. Simulations Using the 100 cm Soil Moisture Profile
4.2. Simulations in All the Zones of the Field for Yield Estimation
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Landscape Position | ||||
---|---|---|---|---|
Soil Depths (cm) | Soil Properties | Lower Zone | Middle Zone ZoneSlope | Upper Zone Land |
0–20 | Sand (%) | 38.0 | 43.8 | 34.3 |
Clay (%) | 44.4 | 36.3 | 46.7 | |
Silt (%) | 17.6 | 19.9 | 19.1 | |
SOM (%) | 2.02 | 1.44 | 1.87 | |
CaCO3 (%) | 5.4 | 26.3 | 35.2 | |
Total N (%) | 0.122 | 0.095 | 0.107 | |
P-Olsen (mg/kg) | 7.54 | 5.68 | 8.00 | |
K (cmol/kg) | 0.80 | 0.44 | 0.48 | |
20–40 | Sand (%) | 40.1 | 47.9 | 31.4 |
Clay (%) | 42.1 | 35.4 | 48.5 | |
Silt (%) | 17.8 | 16.7 | 19.8 | |
SOM (%) | 1.68 | 1.29 | 1.60 | |
CaCO3 (%) | 5.1 | 24.5 | 41.5 | |
Total N (%) | 0.108 | 0.087 | 0.098 | |
P-Olsen (mg/kg) | 3.69 | 3.53 | 5.38 | |
K (cmol/kg) | 0.65 | 0.39 | 0.39 |
A. Conservative Crop Parameters | |
---|---|
Base temperature (°C) below which crop development does not progress | 0.0 |
Upper temperature (°C) above which crop development no longer increases with an increase in temperature | 26.0 |
Crop coefficient when canopy is complete but prior to senescence (KcTr, x) | 1.10 |
Water productivity normalized for ETo and CO2 (WP*) (g/m2) | 15.0 |
Possible increase (%) in HI due to water stress before flowering | 5 |
Coefficient describing positive impact on HI of restricted vegetative growth during yield formation | 10.0 |
Coefficient describing negative impact on HI of stomatal closure during yield formation | 7.0 |
Allowable maximum increase (%) in specified HI | 15 |
Soil water depletion factor for canopy expansion (p-exp)—Upper threshold | 0.20 |
Soil water depletion factor for canopy expansion (p-exp)—Lower threshold | 0.65 |
Soil water depletion fraction for stomatal control (p-sto)—Upper threshold | 0.65 |
Soil water depletion factor for canopy senescence (p-sen)—Upper threshold | 0.70 |
Minimum growing degrees required for full crop transpiration (°C—day) | 14.0 |
B. Fine-Tuned Non-conservative Parameters | |
Number of Plants per Hectare | 185,000 |
Degree Days: from sowing to emergence | 150 |
Degree Days: from sowing to max. canopy | 1186 |
Degree Days: from sowing to flowering | 1250 |
Degree Days: from sowing to senescence | 1700 |
Degree Days: from sowing to maturity | 2400 |
Maximum canopy cover (CCx) in fraction soil cover | 0.96 |
Maximum effective rooting depth (m) | 1.00 |
Average root zone expansion (cm/day) | 0.9 |
Reference Harvest Index (HIo) (%) | 48 |
Field zone | Block4 | Block3 | Block2 | Block1 | ||||||||
(0–20) cm | ||||||||||||
Preplant | Farmer | VRT | Farmer | VRT | Preplant | VRT | Preplant | Farmer | VRT | Farmer | Preplant | |
Upper | C | C | C | C | C | SC | C | C | C/CL | C/CL | CL | C |
Middle | C | C | C | SCL | CL/SCL | SC/CL | CL | SC/SCL | SC/CL/SCL | SCL | L | SC/SCL |
Lower | CL | C | CL | C | C | C | C | C | C | C | C | C |
(20–40) cm | ||||||||||||
Upper | C | C | C | C | C | C/SC | SC | C | CL | CL | SC | SC/CL |
Middle | CL | C | C | SC/SCL | CL | SCL | SCL | C | SCL | SCL | SCL | SC |
Lower | C | C | CL | C | C | C | C | C | C | C | C | C |
Treatment | Measured Yield (kg/ha) | Simulated Yield (kg/ha) | Fertility Level |
---|---|---|---|
2015–2016 VRA low | 9220 | 8793 | 100% |
2015–2016 VRA mid | 5380 | 5410 | 59% |
2016–2017 VRA low | 5340 | 5336 | 72% |
2016–2017 VRA mid | 2070 | 2115 | 24% |
2016–2017 Farm mid | 1860 | 1835 | 21% |
2016–2017 VRA up | 3020 | 3010 | 34% |
Treatment | E (mm) | T (mm) | R (mm) | D (mm) | R |
---|---|---|---|---|---|
2015–2016 VRA low | 43 | 250.2 | 32.6 | 39.8 | 0.58 |
2015–2016 VRA mid | 77.7 | 201.8 | 22.7 | 52.9 | 0.82 |
2016–2017 VRA low | 106.7 | 216.1 | 12.8 | 8.2 | 0.95 |
2016–2017 VRA mid | 162 | 134.4 | 15.2 | 16 | 0.89 |
2016–2017 Farm mid | 168.8 | 120.5 | 15.7 | 57.1 | 0.94 |
2016–2017 VRA up | 118.5 | 206.3 | 30.3 | 0 | 0.82 |
Lowland | Slope | Upland | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|
2015–2016 Cult. Per. | Treatment | Yield Meas | Fertility | YieldSim | Average Fertility | Yield Meas | Fertility | YieldSim | Average Fertility | Yield Meas | Fertility | YieldSim | Average Fertility |
Block2 | Preplant a | 7700 | 86% | 7730 | 81% | 5150 | 56% | 5140 | 70% | 7010 | 77% | 7050 | 72% |
Block3 | Preplant a | 6920 | 76% | 6930 | 7560 | 84% | 7530 | 6110 | 67% | 6160 | |||
Block2 | Farmer a | 6380 | 69% | 6320 | 79% | 4290 | 46% | 4320 | 61% | 6380 | 70% | 6410 | 66% |
Block3 | Farmer a | 7910 | 89% | 7930 | 6720 | 75% | 6780 | 5690 | 62% | 5720 | |||
Block2 | VRA a | 9220 | 100% * | 8790 | 90% | 5380 | 59% * | 5410 | 78% | 6700 | 74% | 6760 | 75% |
Block3 | VRA a | 7190 | 79% | 7170 | 8520 | 97% | 8540 | 6890 | 75% | 6870 | |||
2016–2017 Cult. Per. | Treatment | Yieldmeas. | Fertility | Yieldsim | Average Fertility | Yieldmeas. | Fertility | Yieldsim | Average Fertility | Yieldmeas. | Fertility | Yieldsim | Average Fertility |
Block2 | Preplant b | 4380 | 53% | 4360 | 53% | 3210 | 37% | 3220 | 32% | 2780 | 30% | 2720 | 27% |
Block3 | Preplant b | 4190 | 52% | 4210 | 2400 | 27% | 2400 | 1990 | 23% | 2020 | |||
Block2 | Farmer b | 4510 | 57% | 4600 | 55% | 1860 | 21% * | 1840 | 27% | 3500 | 40% | 3480 | 33% |
Block3 | Farmer b | 4350 | 53% | 4360 | 2860 | 32% | 2870 | 2210 | 25% | 2210 | |||
Block2 | VRA b | 5340 | 72% * | 5370 | 63% | 2070 | 24% * | 2120 | 27% | 2960 | 34% * | 2910 | 39% |
Block3 | VRA b | 4440 | 54% | 4440 | 2700 | 30% | 2690 | 3810 | 45% | 3850 |
Lower Zone | Middle Zone | Upper Zone | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
2015–2016 Cult. Per. | Treatment | Yieldmeas | Fertility * | Yield sim | Yieldmeas | Fertility * | Yield sim | Yieldmeas | Fertility * | Yield sim |
Block1 | Preplant | 4990 | 81% | 7340 | 5920 | 70% | 6410 | 4390 | 72% | 6610 |
Block4 | Preplant | 6270 | 7340 | 6350 | 6410 | 6680 | 6610 | |||
Block1 | Farmer | 6090 | 79% | 7170 | 3370 | 61% | 5610 | 5860 | 66% | 6060 |
Block4 | Farmer | 5610 | 7170 | 7920 | 5620 | 6260 | 6060 | |||
Block1 | VRA | 7470 | 90% | 8070 | 3630 | 78% | 7030 | 5990 | 75% | 6870 |
Block4 | VRA | 7190 | 8070 | 8870 | 7120 | 5880 | 6870 | |||
2016–2017 Cult. Per. | Treatment | Yieldmeas | Fertility * | Yield im | Yieldmeas | Fertility * | Yield sim | Yieldmeas | Fertility * | Yield sim |
Block1 | Preplant | 3200 | 53% | 4360 | 1220 | 32% | 2970 | 1740 | 27% | 2410 |
Block4 | Preplant | 4000 | 4360 | 2750 | 2990 | 2950 | 2410 | |||
Block1 | Farmer | 3320 | 55% | 4440 | 3280 | 27% | 2400 | 2870 | 33% | 2940 |
Block4 | Farmer | 4110 | 4440 | 4170 | 2420 | 3210 | 2940 | |||
Block1 | VRA | 4670 | 63% | 4990 | 2610 | 27% | 2420 | 2900 | 39% | 3260 |
Block4 | VRA | 3740 | 4990 | 4130 | 2420 | 3020 | 3260 |
Variation in Simulated vs. Measured Yield (%) | ||||
---|---|---|---|---|
2015–2016 Growing Season | Treatment | Lower Zone | Middle Zone | Upper Zone |
Block1 | Preplant | +47.09 | +8.28 | +50.57 |
Block4 | Preplant | +17.07 | +0.94 | −1.05 |
Block1 | Farmer | +17.73 | +66.47 | +3.41 |
Block4 | Farmer | +27.81 | −29.04 | −3.19 |
Block1 | VRA | +8.03 | +93.66 | +14.69 |
Block4 | VRA | +12.24 | −19.73 | +16.84 |
2016–2017 Growing Season | ||||
Block1 | Preplant | +36.25 | +143.44 | +38.51 |
Block4 | Preplant | +9.00 | +8.73 | −18.31 |
Block1 | Farmer | +33.73 | −26.83 | +2.44 |
Block4 | Farmer | +8.03 | −1.97 | −8.41 |
Block1 | VRA | +6.85 | −7.28 | +12.41 |
Block4 | VRA | +33.42 | −41.40 | +7.95 |
Data | Equation | R2 |
---|---|---|
Total Field | y = 0.8913x | 0.95 |
Upper Zone | y = 0.9059x | 0.98 |
Middle Zone | y = 0.9666x | 0.89 |
Lower Zone | y = 0.8358x | 0.99 |
Yield Measured | Fertility Factor % | Yield Simulated | |
---|---|---|---|
Yield measured | 1.0000 | 0.9718 *** | 0.9736 *** |
Fertility factor % | 1.0000 | 0.9990 *** | |
Yield simulated | 1.0000 |
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Dercas, N.; Dalezios, N.R.; Stamatiadis, S.; Evangelou, E.; Glampedakis, A.; Mantonanakis, G.; Tserlikakis, N. AquaCrop Simulation of Winter Wheat under Different N Management Practices. Hydrology 2022, 9, 56. https://doi.org/10.3390/hydrology9040056
Dercas N, Dalezios NR, Stamatiadis S, Evangelou E, Glampedakis A, Mantonanakis G, Tserlikakis N. AquaCrop Simulation of Winter Wheat under Different N Management Practices. Hydrology. 2022; 9(4):56. https://doi.org/10.3390/hydrology9040056
Chicago/Turabian StyleDercas, Nicholas, Nicolas R. Dalezios, Stamatis Stamatiadis, Eleftherios Evangelou, Antonios Glampedakis, Georgios Mantonanakis, and Nicholaos Tserlikakis. 2022. "AquaCrop Simulation of Winter Wheat under Different N Management Practices" Hydrology 9, no. 4: 56. https://doi.org/10.3390/hydrology9040056
APA StyleDercas, N., Dalezios, N. R., Stamatiadis, S., Evangelou, E., Glampedakis, A., Mantonanakis, G., & Tserlikakis, N. (2022). AquaCrop Simulation of Winter Wheat under Different N Management Practices. Hydrology, 9(4), 56. https://doi.org/10.3390/hydrology9040056