posted on 2024-05-17, 19:07authored byChuan-Wang Yang, Ge Xie, Li Yuan, Yi Hu, Guo-Ping Sheng
Nanoagrochemicals
present promising solutions for augmenting
conventional
agriculture, while insufficient utilization of nanobiointerfacial
interactions hinders their field application. This work investigates
the multiscale physiochemical interactions between nanoagrochemicals
and rice (Oryza sativa L.) leaves and
devises a strategy for elevating targeting efficiency of nanoagrochemicals
and stress resilience of rice. We identified multiple deposition behaviors
of nanoagrochemicals on hierarchically structured leaves and demonstrated
the crucial role of leaf microarchitectures. A transition from the
Cassie–Baxter to the Wenzel state significantly changed the
deposition behavior from superlattice assembly, ring-shaped aggregation
to uniform monolayer deposition. By fine-tuning the formulation properties,
we achieved a 415.9-fold surge in retention efficiency, and enhanced
the sustainability of nanoagrochemicals by minimizing loss during
long-term application. This biointerface design significantly relieved
the growth inhibition of Cd(II) pollutant on rice plants with a 95.2%
increase in biomass after foliar application of SiO2 nanoagrochemicals.
Our research elucidates the intricate interplay between leaf structural
attributes, nanobiointerface design, and biological responses of plants,
fostering field application of nanoagrochemicals.