A general Metal-Ion-Modification route for preparing hydrophobic paper and tableware from lignocellulose fibers.

[Display omitted] • A general metal-ion-modification (MIM) route is invented to execute wettability transition of lignocellulose materials. • Approximately 3 mg of metal ions (e.g., Fe3+ and Zr4+) can turn 1 g hydrophilic of kraft pulps to hydrophobic ones. • Metal coordination-induced self-assembly of nanofibrils is responsible for the wettability transition of lignocellulose. • MIM-derived hydrophobic paper and tableware are economic feasible, safe, biodegradable, and recyclable. Inherent hydrophilicity and poor water resistance prevent using lignocellulosic materials as green plastic alternatives to fossil fuel-based plastics. Here, we report a facile metal-ion-modification (MIM) route, swelling with aqueous metal ion solutions, and drying to convert conventional hydrophilic paper and wood pulp into biodegradable hydrophobic paper and tableware without the addition of hydrophobic sizing chemicals/materials. Metal ions such as Fe3+ and Zr4+ can coordinate with pulp fibers' polar groups (i.e., OH, C O, and COOH) that induce self-assembly of their surface fibrillated "hairy" cellulose nanofibrils to form a more compact structure with fewer available OH groups for water sorption. This decreases the surface energy of pulp fibers and increases their hydrophobicity and water resistance. Only ∼3 mg of metal ions is needed to induce the wettability transition in 1 g of kraft pulp, resulting in hydrophobic paper and tableware with water contact angles (WCAs) of 120–140°. The coordinated Fe3+ and Zr4+ are stable, with negligible metal leaching during use, allowing the hydrophobic paper and tableware to be used for food packaging. This MIM technique can be integrated into the existing paper-making process for the scalable production of hydrophobic papers and tableware, providing an alternative route for developing sustainable and biodegradable plastic counterparts. [ABSTRACT FROM AUTHOR]