Traditional approaches to synthesizing hydrophobic materials have long been plagued by inherent limitations, typically relying on energy-intensive high-temperature processes, environmentally harmful organic solvents, and expensive coupling agents that generate toxic byproducts. Now, a paradigm-shifting study published in the Journal of Bioresources and Bioproducts demonstrates that the most abundant substance on Earth—water—can serve as a powerful catalyst for creating advanced functional materials from renewable resources.
The breakthrough lies in the elegant simplicity of mechanochemical activation. By employing a ball milling process with trace amounts of water, researchers successfully activated sodium methylsilicate to generate highly reactive hydroxyl groups, which subsequently undergo condensation reactions with diverse substrates to form robust three-dimensional network structures with inherent porosity and exceptional hydrophobic characteristics. What distinguishes this methodology is its remarkable substrate versatility: the system accommodates over 40 different materials through distinct connection strategies, including small molecules, linear polymers like cellulose, planar polymers such as lignin, and even untreated plant tissues where intrinsic water content initiates the reaction without additional processing.
The environmental credentials extend beyond solvent elimination. The reaction mechanism inherently captures atmospheric carbon dioxide, converting it into sodium bicarbonate as a valuable byproduct—transforming material synthesis from a carbon-intensive process into a carbon-negative operation. Performance characterization reveals materials with surface areas of 129–388 m 2 /g and superhydrophobic behavior with contact angles exceeding 150°.
Practical applications validate the technological potential across diverse sectors. In oil-water separation, reed-derived materials achieved petroleum ether permeability exceeding 801 L/(m 2 ·h) under gravity-driven conditions. For pharmaceutical waste management, lignin-based materials demonstrated 85% removal efficiency for propofol. The materials also exhibited exceptional catalytic degradation capabilities, achieving 90–99.99% removal rates for industrial dyes. Significantly, the methodology demonstrates genuine scalability, with successful production at the decagram scale while maintaining consistent structural properties—positioning the technology for practical industrial implementation.
See the article:
DOI
https://doi.org/10.1016/j.jobab.2026.100247
Original Source URL
https://www.sciencedirect.com/science/article/pii/S2369969826000198
Journal
Journal of Bioresources and Bioproducts
Experimental study
Not applicable
H2O As an Efficient Green Initiator to Construct Renewable Hydrophobic Porous Materials for Pollutant Removal
20-Feb-2026