Distinct accumulation patterns, translocation efficiencies, and impacts of nano-fertilizer and nano-pesticide in wheat through foliar versus soil application

The use of nano-chemicals in agriculture has been shown to enhance crop production through soil additions or foliar sprays. However, the accumulation pattern, translocation efficiency, mode of action of nanomaterials (NMs) via different application methods remain unclear. In this study, wheat was treated with CuO-NPs/CeO₂-NPs (50 and 100 nm) for 21 days using soil and foliar application separately. Foliar spray resulted in higher accumulation and more efficient translocation of NMs compared to soil addition. Smaller NMs exhibited higher accumulation and transfer capabilities under the same application method. The accumulation of CuO-NPs was approximately 20 times greater than that of CeO₂-NPs, particularly under the soil addition treatment. Scanning electron microscopy analysis demonstrated that NMs could directly enter wheat leaves via stomata during foliar application. Wheat growth was inhibited by roughly 15 % following CuO-NPs exposure, whereas no significant effects on growth were observed with CeO₂-NPs. By integrating nontargeted metabolomics analysis with targeted physiological characteristics assessments, it was revealed that CuO-NPs mainly disturbed nitrogen metabolism pathways and induced oxidative damage. In contrast, CeO₂-NPs enhanced carbohydrates related biological processes such as starch and sucrose metabolism, glycolysis, and TCA cycle, which are crucial for carbon metabolism. These findings suggest that the type of nanomaterial is a crucial factor to consider when evaluating their foliar or soil application in agriculture.