Fertilization and soil management machine learning based sustainable agronomic prescriptions for durum wheat in Italy

Purpose This research aims to develop a meta-machine learning model to optimize soil and nitrogen management for durum wheat in Italy. It addresses the challenges of increased food production on limited land amidst rising input costs, geopolitical changes, and climate change. The goal is to aid decision-makers in achieving maximum crop yield and income margins through efective agronomic strategies. Methods The study developed a meta-machine learning model, integrating classifcation and regression models, and tested it at four sites in Marche and Basilicata, Italy, over several years. The model incorporated data from remote sensing, crop phenology, soil chemical properties, weather data, soil management, and nitrogen levels. A Random Forest model was used to classify crop phenology, while a Neural Network model predicted yield. Eleven nitrogen levels were compared across these sites. Results The Random Forest model achieved an accuracy of 0.98, kappa of 0.96, and recall of 0.98 for predicting crop phenology. The Neural Network model for yield prediction had an R squared of 0.90 and a Root Mean Square Error of 0.59 t ha-1. Key factors identifed for model accuracy were temperature, precipitation, NDVI, and nitrogen input. Simulations of 30 soil management and fertilization combinations revealed that no-tillage management increased grain yield. The Marginal Fertilizer Yield Index determined optimal nitrogen application. Conclusions The meta-machine learning model accurately predicted durum wheat yield and identifed efective agronomic strategies, demonstrating the potential for broader application in feld conditions. The model ofers a promising approach to sustainable agriculture and climate change mitigation by utilising publicly available spatial datasets.