Potential for degradation of lignocellulosic biomass via alkaline pretreatment using corn crop residual biomass

Angulo-Padilla, Julian; Ossa, Luisa Lozano-De La; González-Delgado, Ángel Darío; Sánchez-Tuirán, Eduardo; Ojeda-Delgado, Karina

doi:10.12988/ces.2018.8263

Cited by 2 publications

(2 citation statements)

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“…− and PO 4 3− removal was enhanced due to surface modification with Al of biochar synthesized from poplar residues [56]. The bromatological composition of corn stalks has been reported, which presents in their structure cellulose (35-50%), hemicelluloses (20-35%), and lignin (15-20%); the quaternization of the structure could be successful when occurred between hydroxyl groups of these lignocellulosic materials [57]. From the EDS images, C, O, S, and K atoms were observed in higher proportions.…”

Section: Characterization Of the Bioadsorbentsmentioning

confidence: 98%

“…As Donnan's theory illustrates [70], anion charge is an essential feature of the yield in the adsorption mechanism; it may lead to selective phosphate adsorption on both adsorbents evaluated against nitrate. Thus, considering that the adsorption of both anions under study has been reported to occur by Van der Waals forces, ion exchange and surface complex formation are involved due to the heterogeneity of their structure and binding sites [8,57].…”

Section: Adsorption Equilibriummentioning

confidence: 99%

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Selective and Binary Adsorption of Anions onto Biochar and Modified Cellulose from Corn Stalks

Tovar

Villabona-Ortíz

González-Delgado

et al. 2023

Water

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Water treatment alternatives such as adsorption using agricultural residues are currently being studied to eliminate pollutants that cause eutrophication in water bodies, avoiding the alteration of aquatic ecosystems. In this work, two bio-adsorbents were prepared using cellulose extracted from corn stems, Zea mays, which were labeled as MC (quaternized cellulose modified with Cetyl trimethyl ammonium chloride) and B 1:1 (biochar obtained by the impregnation of the biomass with an H2SO4 solution, 50% v/v, using a ratio of 1:1% weight of biomass to volume, followed by carbonization at 520 °C for 30 min with a heating rate of 10 °C/min). FTIR, TGA, DSC, and SEM-EDS were used to study the properties of the bio-adsorbents. The effect of temperature over nitrate and phosphate adsorption in the selective and binary system at 100 mg/L was tested at five temperatures: 25, 30, 35, 40, and 45 °C, using a load of the pollutant of 100 mg/L, volume of 5 mL, and a rate of bio-adsorbent of 2 g/L at 200 rpm. Results showed a phosphate removal of 29.1% using the B 1:1 bio-adsorbent at 30 °C and 23.8% with the MC bio-adsorbent at 35 °C. In the case of nitrate, removal of 40% was determined with the B 1:1 bio-adsorbent at 25 °C, while removal of 38.5% was attained at 30 °C after using the MC bio-adsorbent. The equilibrium was reached at 420 min. Nitrate adsorption with the MC sample showed a good adjustment to the pseudo-second-order model. The pseudo-first-order model described the kinetics of phosphate removal with MC, while this model had a good fit with the B 1:1 sample for nitrate and phosphate. Freundlich’s model also adjusted the adsorption equilibrium for both anions with acceptable accuracy. Moreover, the binary study indicated selectivity for the phosphate, suggesting the potential applications of the carbon-based bio-adsorbents for anionic ions remotion in aqueous media.

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Section: Characterization Of the Bioadsorbentsmentioning

confidence: 98%