Wood Biomolecules as Agricultural Adjuvants for Effective Suppression of Droplet Rebound from Plant Foliage

Mamata Bhattarai; Hedar Al‐Terke; Kai Liu; Zhangmin Wan; Petri Kilpeläinen; Alistair W. T. King; Alexey Khakalo; Jiayun Xu; Chunlin Xu; Robin H. A. Ras; Bruno D. Mattos; Orlando J. Rojas

doi:10.1002/advs.202416686

Wood Biomolecules as Agricultural Adjuvants for Effective Suppression of Droplet Rebound from Plant Foliage

Mamata Bhattarai^*, Hedar Al‐Terke, Kai Liu, Zhangmin Wan, Petri Kilpeläinen, Alistair W. T. King, Alexey Khakalo, Jiayun Xu, Chunlin Xu, Robin H. A. Ras, Bruno D. Mattos^*, Orlando J. Rojas^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

Abstract

The agrochemical run-off associated with crop control is an unintended consequence of droplet rebound from plant foliage, which negatively affects crop performance and the environment. This is most critical in water-based formulations delivered on plant surfaces that are typically waxy and nonwetting. This study introduces an alternative to synthetic surfactants and high molecular weight polymers that are used as spreading agents for agrochemicals. Specifically, biopolymeric adjuvants (hemicelluloses and oligomeric lignin) extracted from wood by pressurized hot water are shown for their synergistic pinning capacity and surface activity that can effectively suppress droplet rebound from hydrophobic surfaces. Hemicellulose and lignin mixtures, alongside several model compounds, are investigated for understanding the dynamics of droplet impact and its correlation with biomacromolecule formations. The benefit of utilizing lean solutions (0.1 wt.% concentration) is highlighted for reducing droplet rebounding from leaves, outperforming synthetic systems in current use. For instance, a tenfold deposition improvement is demonstrated on citrus leaves, because of a significantly suppressed droplet roll-off. These results establish the excellent prospects of wood extracts to improve crop performance.

Original language	English
Article number	2416686
Journal	Advanced Science
DOIs	https://doi.org/10.1002/advs.202416686
Publication status	Accepted/In press - 10 Mar 2025
MoE publication type	A1 Journal article-refereed

Funding

This work was supported by the European Research Council, H2020 (Project No. 788489), the Canada Excellence Research Chairs, Government of Canada (CERC-2018-00006), the Academy of Finland's Flagship Programme – Competence Center for Materials Bioeconomy, FinnCERES (Project Nos. 318890 and 318891), and the Academy of Finland, Life-Inspired Hybrid Materials (2022-2029) (Project No. 346109). Natural Resources Institute Finland (Luke) supported this work from Project Positive Fibers (41007-00212300).

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@article{c2da4366936540648b791c1b4f875bf2,

title = "Wood Biomolecules as Agricultural Adjuvants for Effective Suppression of Droplet Rebound from Plant Foliage",

abstract = "The agrochemical run-off associated with crop control is an unintended consequence of droplet rebound from plant foliage, which negatively affects crop performance and the environment. This is most critical in water-based formulations delivered on plant surfaces that are typically waxy and nonwetting. This study introduces an alternative to synthetic surfactants and high molecular weight polymers that are used as spreading agents for agrochemicals. Specifically, biopolymeric adjuvants (hemicelluloses and oligomeric lignin) extracted from wood by pressurized hot water are shown for their synergistic pinning capacity and surface activity that can effectively suppress droplet rebound from hydrophobic surfaces. Hemicellulose and lignin mixtures, alongside several model compounds, are investigated for understanding the dynamics of droplet impact and its correlation with biomacromolecule formations. The benefit of utilizing lean solutions (0.1 wt.% concentration) is highlighted for reducing droplet rebounding from leaves, outperforming synthetic systems in current use. For instance, a tenfold deposition improvement is demonstrated on citrus leaves, because of a significantly suppressed droplet roll-off. These results establish the excellent prospects of wood extracts to improve crop performance.",

author = "Mamata Bhattarai and Hedar Al‐Terke and Kai Liu and Zhangmin Wan and Petri Kilpel{\"a}inen and King, {Alistair W. T.} and Alexey Khakalo and Jiayun Xu and Chunlin Xu and Ras, {Robin H. A.} and Mattos, {Bruno D.} and Rojas, {Orlando J.}",

year = "2025",

month = mar,

day = "10",

doi = "10.1002/advs.202416686",

language = "English",

journal = "Advanced Science",

issn = "2198-3844",

publisher = "Wiley",

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T1 - Wood Biomolecules as Agricultural Adjuvants for Effective Suppression of Droplet Rebound from Plant Foliage

AU - Bhattarai, Mamata

AU - Al‐Terke, Hedar

AU - Liu, Kai

AU - Wan, Zhangmin

AU - Kilpeläinen, Petri

AU - King, Alistair W. T.

AU - Khakalo, Alexey

AU - Xu, Jiayun

AU - Xu, Chunlin

AU - Ras, Robin H. A.

AU - Mattos, Bruno D.

AU - Rojas, Orlando J.

PY - 2025/3/10

Y1 - 2025/3/10

N2 - The agrochemical run-off associated with crop control is an unintended consequence of droplet rebound from plant foliage, which negatively affects crop performance and the environment. This is most critical in water-based formulations delivered on plant surfaces that are typically waxy and nonwetting. This study introduces an alternative to synthetic surfactants and high molecular weight polymers that are used as spreading agents for agrochemicals. Specifically, biopolymeric adjuvants (hemicelluloses and oligomeric lignin) extracted from wood by pressurized hot water are shown for their synergistic pinning capacity and surface activity that can effectively suppress droplet rebound from hydrophobic surfaces. Hemicellulose and lignin mixtures, alongside several model compounds, are investigated for understanding the dynamics of droplet impact and its correlation with biomacromolecule formations. The benefit of utilizing lean solutions (0.1 wt.% concentration) is highlighted for reducing droplet rebounding from leaves, outperforming synthetic systems in current use. For instance, a tenfold deposition improvement is demonstrated on citrus leaves, because of a significantly suppressed droplet roll-off. These results establish the excellent prospects of wood extracts to improve crop performance.

AB - The agrochemical run-off associated with crop control is an unintended consequence of droplet rebound from plant foliage, which negatively affects crop performance and the environment. This is most critical in water-based formulations delivered on plant surfaces that are typically waxy and nonwetting. This study introduces an alternative to synthetic surfactants and high molecular weight polymers that are used as spreading agents for agrochemicals. Specifically, biopolymeric adjuvants (hemicelluloses and oligomeric lignin) extracted from wood by pressurized hot water are shown for their synergistic pinning capacity and surface activity that can effectively suppress droplet rebound from hydrophobic surfaces. Hemicellulose and lignin mixtures, alongside several model compounds, are investigated for understanding the dynamics of droplet impact and its correlation with biomacromolecule formations. The benefit of utilizing lean solutions (0.1 wt.% concentration) is highlighted for reducing droplet rebounding from leaves, outperforming synthetic systems in current use. For instance, a tenfold deposition improvement is demonstrated on citrus leaves, because of a significantly suppressed droplet roll-off. These results establish the excellent prospects of wood extracts to improve crop performance.

U2 - 10.1002/advs.202416686

DO - 10.1002/advs.202416686

M3 - Article

SN - 2198-3844

JO - Advanced Science

JF - Advanced Science

M1 - 2416686

ER -

Wood Biomolecules as Agricultural Adjuvants for Effective Suppression of Droplet Rebound from Plant Foliage

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