Control the Entire Journey of Pesticide Application on Superhydrophobic Plant Surface by Dynamic Covalent Trimeric Surfactant Coacervation

Liu, Bin; Fan, Yaxun; Li, Haofei; Zhao, Weiwei; Luo, Siqi; Wang, Hua; Guan, Bo; Li, Qiaolian; Yue, Jiling; Dong, Zhichao; Wang, Yilin; Jiang, Lei

doi:10.1002/adfm.202006606

Cited by 98 publications

(101 citation statements)

References 48 publications

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“…Abamectin‐loaded silica particles modified with PDA can improve the adhesion of abamectin on the leaf surface 16 . Synthesized imine‐based dynamic covalent surfactants can participate in the formation of MCs that have superior affinity for epicuticular wax and microstructures/nanostructures of highly hydrophobic leaf surfaces 17 . The rapid development of nanotechnology has witnessed great breakthroughs in controlled‐release, targeted release and interaction with target surfaces 18…”

Section: Introductionmentioning

confidence: 99%

Improving the efficacy against crop foliage disease by regulating fungicide adhesion on leaves with soft microcapsules

Pan

Cao

et al. 2021

Pest Management Science

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BACKGROUND Increasing pesticide retention on crop leaves is a key approach for guaranteeing efficacy when products are applied to foliage. Evidently, the formulation plays an important role in this process. Microcapsules (MCs) are a promising formulation, but whether and how their adhesion to the leaf surface affects retention and efficacy is not well understood. RESULTS In this study, we found that the incorporation of polyethylene glycol (PEG) with different molecular weights into the MC shell affects the release profile of MCs and the contact area of these MCs to leaves by changing their softness. The cumulative release rates of pyraclostrobin (Pyr) MCs fabricated with PEG200, PEG400, PEG800 and PEG1500 were 80.61%, 90.98%, 94.07% and 97.40%, respectively. Scanning electron microscopy observations showed that the flexibility of the MCs increased with increasing PEG molecular weight. The median lethal concentration (LC50) of the MCs with different PEG to the zebrafish were 12.10, 8.10, 3.90 and 1.46 mg L−1, respectively, which also indirectly reflected their release rate. Rainwater had less influence on the retention of the MCs prepared with PEG1500 than with the other PEG, which indicates a better adhesion to the target leave surfaces. MCs with the highest residual efficacy had better control efficacy on peanut leaf spot in field trials. CONCLUSION Overall, adding PEG with an appropriate molecular weight to the MC shell can regulate the structure of the MC shell to improve the affinity between the MCs and leaves, which further improves the utilization of pesticides and reduces the environmental risks of pesticides. © 2021 Society of Chemical Industry.

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Section: Introductionmentioning

confidence: 99%

Improving the efficacy against crop foliage disease by regulating fungicide adhesion on leaves with soft microcapsules

Pan

Cao

et al. 2021

Pest Management Science

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“…The imine groups of the surfactant could be hydrolyzed in acidic environment created by CO 2 to release pesticides [1] APTES and TEOS /Kasugamycin Kasugamycin was conjugated with APTES and then forming pesticide-contained silica NPs via sol-gel method Amidase in pathogenic microorganisms could disintegrate the nanopesticide to release kasugamycin [57] pH-Jump Reagent 2,4-Dinitrobenzaldehyde and Zeolitic Imidazolate Framework-8 (MOF)/Prochloraz In situ addition of prochloraz and pH-jump reagent in the synthesis process of the MOF structure UV light makes pH-jump reagent to acidify the environment, interrupting the MOF structure to release prochloraz [65] formed the surface valve layer.…”

Section: Valve-regulated Release Nanopesticidesmentioning

confidence: 99%

“…When exposed to acidic conditions, the protonation of amino groups in chitosan would cause a gradual solubilization of the chitosan matrix, resulting release of spinosad with regulated rates for 6 days. Liu et al [1] synthesized an oligomeric imine-based surfactant, which could be assembled into worm-like micelles and could entrap both hydrophilic and hydrophobic pesticides; once applied, the materials would absorb CO 2 from air and create an acidic environment, hydrolyzing the imine groups and initiating the release of active loadings. Covalent grafting was also employed for the fabrication of integral stimulated release nanopesticides.…”

Section: Integral Stimulated-release Nanopesticidesmentioning

confidence: 99%

“…The rapidly growing demands in sustainable economy set forth grand challenges to current agricultural industry that have traditionally relied heavily on agrochemicals, including synthetic pesticides and fertilizers. Up to now, the global use of pesticides and fertilizers have reached over 4.1 and 125 million tons, respectively [1,2]; however, the traditional way of administering agrochemicals is generally inefficient. For pesticides, which are generally synthetic organic compounds with high hydrophobicity and often poor chemical stability, it is estimated that only less than 1% of the applied dosage served the purpose, while the majority get lost to environment via volatilization, degradation, and photolysis in traditional application scenarios [3,4].…”

Section: Introductionmentioning

confidence: 99%

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Recent development in functional nanomaterials for sustainable and smart agricultural chemical technologies

2022

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New advances in nanotechnology are driving a wave of technology revolution impacting a broad range of areas in agricultural production. The current work reviews nanopesticides, nano-fabricated fertilizers, and nano activity-based growth promoters reported in the last several years, focusing on mechanisms revealed for preparation and functioning. It appears to us that with many fundamental concepts have been demonstrated over last two decades, new advances in this area continue to expand mainly in three directions, i.e., efficiency improvement, material sustainability and environment-specific stimulation functionalities. It is also evident that environmental and health concerns associated with nano agrochemicals are the primary motivation and focus for most recent work. Challenges and perspectives for future development of nano agrochemicals are also discussed.

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“…Selected engineered nanomaterials have been applied as soil amendments, seed coatings, and foliar sprays [35,36]. To meet the goal of controlled release and delivery of active ingredients with reasonable environmental cost and energy input, nanomaterials need to be carefully designed and applied by sustainable methods [23,35,37]. For nanomaterials applied as fertilizers, there has been work on both nanoscale macro- [38][39][40][41] and micronutrients [42][43][44][45].…”

Section: Introductionmentioning

confidence: 99%

Effects of Phosphorus Ensembled Nanomaterials on Nutrient Uptake and Distribution in Glycine max L. under Simulated Precipitation

White

et al. 2021

Agronomy

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Nanoscale hydroxyapatite (nHA) was synthesized to investigate its potential as a phosphorus (P) ensembled nanofertilizer, using soybean (Glycine max L.) as a model plant. The conventional analogue phosphate (pi) was used for comparison with the synthesized nHA. Varied precipitation intensities (0%, 30%, 60%, and 100%) were simulated by adding selected volumes of the P fertilizers (nHA or pi) via foliar spray and soil amendment. The total amounts of added P were the same across all the treatments. The importance of a wash-off effect was investigated on foliar-treated seedlings by evaluating different watering heights (20, 120, and 240 cm above the seedlings). Fresh weight, pigment content, macro-, and micronutrient contents were measured in soybean tissues across all the treatments after 4 weeks of greenhouse cultivation. The synthesized nHA showed superior effects on plant nutrient content upon high precipitation intensities. For example, at 100% precipitation intensity, there was 32.6% more P and 33.2% more Ca in shoots, 40.6% more P and 45.4% more Ca in roots, and 37.9% more P and 82.3% more Ca in pods, as compared to those with pi treatment, respectively. No impact on soybean biomass was evident upon the application of nHA or pi. Further investigation into customizing nHA to enhance its affinity with crop leaves and to extend retention time on the leaf surface is warranted given that the present study did not show significant positive impacts of nHA on soybean growth under the effects of precipitation. Taken together, our findings increase understanding of the potential application of nHA as a nano-enabled fertilizer in sustainable agriculture.

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Control the Entire Journey of Pesticide Application on Superhydrophobic Plant Surface by Dynamic Covalent Trimeric Surfactant Coacervation

Cited by 98 publications

References 48 publications

Improving the efficacy against crop foliage disease by regulating fungicide adhesion on leaves with soft microcapsules

Improving the efficacy against crop foliage disease by regulating fungicide adhesion on leaves with soft microcapsules

Recent development in functional nanomaterials for sustainable and smart agricultural chemical technologies

Effects of Phosphorus Ensembled Nanomaterials on Nutrient Uptake and Distribution in Glycine max L. under Simulated Precipitation

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