The widespread use of pesticides in agriculture poses food safety and environmental risks, highlighting the need for rapid detection techniques to mitigate contamination. Surface-enhanced Raman spectroscopy (SERS) coupled with machine learning provides a powerful approach for the detection and quantification of multiple pesticides in agricultural products. This study introduces the SERSFormer-2.0 model, which excels in both multilabel classification and multiregression tasks for pesticide analysis, leveraging the power of transformer-based machine learning architectures. SERSFormer-2.0 employs novel multitask learning approach with task specific feature representation layers, shared multihead attention transformer encoder, and task-specific output layers to detect pesticides and estimate the precise concentrations of each pesticide simultaneously. By utilizing core-shell gold-silver nanoparticles, the model achieves near-perfect performance in identifying and quantifying pesticide residues, with multilabel metrics and regression accuracy demonstrating exceptional reliability (accuracy = 0.999; F1 score = 0.992; precision = 0.990; recall = 0.996). A detailed examination of the Raman spectra reveals the predominant influence of certain pesticides, and the mechanisms behind spectral dominance were elucidated. Our findings underscore the SERSFormer-2.0 model 's robustness and its potential to detect mixed contaminants in agricultural products, enhancing food safety and regulatory practices.
Keywords: SERS; artificial intelligence; machine learning; pesticide; transformer.