Role of Nitrogen Fertilization and Sowing Date in Productivity and Climate Change Adaptation Forecast in Rice–Wheat Cropping System

Global food security is at risk due to climate change. Soil fertility loss is among the impacts of climate change which reduces the productivity of rice–wheat cropping systems. This study investigated the effects of varying nitrogen levels and transplanting/sowing dates on the grain yield (GY) and b...

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Bibliographic Details
Published in:Nitrogen (Basel, Switzerland) Switzerland), 2024-12, Vol.5 (4), p.977-991
Main Authors: Hussain, Khalid, Hakki, Erdoğan Eşref, Ilyas, Ayesha, Gezgin, Sait, Kamran, Muhammad Asif
Format: Article
Language:English
Subjects:
21st century
Adaptation
Agricultural production
Agriculture
agronomic management
Air pollution
APSIM model
Biological effects
Carbon dioxide
Carbon dioxide concentration
Cereal crops
Climate adaptation
Climate change
Climate models
Climate prediction
Climatic changes
Crop yield
Cropping systems
Crops
Cultivars
Drought
DSSAT model
Emission standards
Environmental impact
Environmental risk
Experiments
Fertilization
fertilizer management
Food security
Food supply
Growing season
Loam soils
Nitrogen
Outdoor air quality
Planting
Potassium
Productivity
Rain
Rice
Root-mean-square errors
Soil fertility
Soil temperature
Statistical models
Temperature
Wheat
Wheat industry
yield forecast
yield loss
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Summary:Global food security is at risk due to climate change. Soil fertility loss is among the impacts of climate change which reduces the productivity of rice–wheat cropping systems. This study investigated the effects of varying nitrogen levels and transplanting/sowing dates on the grain yield (GY) and biological yield (BY) of rice and wheat cultivars over two growing seasons (2017–2019). Additionally, the impact of climate change on the productivity of both crops was tested under a 1.5 °C temperature increase and 510 ppm CO2 concentration while nitrogen fertilization and sowing window adjustments were evaluated as adaptation options using the DSSAT and APSIM models. Results indicated that the application of 120 kg N ha−1 significantly enhanced both GY and BY in all rice cultivars. The highest wheat yields were obtained with 140 kg N ha−1 for all cultivars. Rice transplanting on the 1st of July and wheat sowing on the 15th of November showed the best yields. The statistical indices of the model’s forecast results were satisfactory for rice (R2 = 0.83–0.85, root mean square error (RMSE) = 341–441, model efficiency (EF) = 0.82–0.89) and wheat (R2 = 0.84–0.89, RMSE = 213–303, EF = 0.88–0.91). Both models predicted yield loss in wheat (20–25%) and rice (28–30%) under a climate change scenario. The models also predicted that increased nitrogen application and earlier planting would be necessary to reduce the impacts of climate change on the productivity of both crops.
ISSN:2504-3129
2504-3129
DOI:10.3390/nitrogen5040062