AI Article Synopsis
- Researchers have developed a high-performance porous carbon adsorbent from biomass (rice husks) using Trichoderma viride, which enhances the material's ability to adsorb organic pollutants.
- The study identifies optimal conditions for creating porous carbon with a remarkable specific surface area of 3714 m²/g, making it one of the most efficient biomass carbons for adsorption in recent research.
- The microbial pretreatment improves the adsorption capacity and kinetics for toluene, demonstrating better performance compared to untreated materials, with notable effects on pore structure and diffusion rates.
Article Abstract
The porous carbon materials formed from biomass precursors are promising candidates for adsorbing organic vapor pollutants. However, these materials have insufficient pores, which hinder their accessibility to adsorbates. This study develops an ultrahigh-surface-area porous carbon adsorbent with interlacing micro-mesoporous structures through Trichoderma viride decomposition. An orthogonal experiment is conducted, and the most suitable conditions for fabricating porous carbon with an ultrahigh S of 3714 m.g and a hierarchical porous structure are identified. This work achieves one of the highest specific surface areas of biomass carbons among recent studies. T. viride corrodes the internal and external microstructures of rice husks, and regulates the lignin, cellulose, and hemicellulose contents, which improve the efficiency of carbonization and chemical activation. The carbonaceous materials with microbial pretreatment exhibit better toluene adsorption performances (100 ppm: 708 mg.g), adsorption rates, and cyclic utilization than those without pretreatment (100 pm: 538 mg.g). In addition, grand canonical Monte Carlo simulation is conducted. The micropores and mesopores created after microbial pretreatment are effective toluene adsorption sites. Moreover, the diffusion coefficient calculated by utilizing Thomas model and Chemical diffusion verify that the mesopores accelerate the kinetic process of toluene adsorption.
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| http://dx.doi.org/10.1016/j.jhazmat.2020.122298 | DOI Listing |
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