Nidia Gallego scite author profile

Biomass pyrolysis to produce biofuel and hydrogen yields large amounts of charred byproducts with low commercial value. A study was conducted to evaluate their potential for being converted into higher value activated carbons by a low-cost process. Six chars derived from various lignocellulosic precursors were activated in CO2 at 800 °C to 30–35% weight loss, and their surface area and porosity were characterized by nitrogen adsorption at 77 K. It was found that, in similar activation conditions, the surface area of the activated carbons correlates with the activation energy of the oxidation reaction by CO2, which in turn varies inversely with the carbon yield after thermolysis in nitrogen at 1000 °C. Since lignin is the most thermally-stable component of lignocellulosic biomass, these results demonstrate, indirectly, that robust, lignin-rich vegetal precursors are to be preferred to produce higher quality activated carbons. The chars derived from white pine (pinus strobus) and chestnut oak (quercus prinus) were converted to activated carbons with the highest surface area (900–1100 m2/g) and largest mesopores volume (0.85–1.06 cm3/g). These activated carbons have properties similar to those of commercially-available activated carbons used successfully for removal of pollutants from aqueous solutions.

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Tensile properties of 3D-printed wood-filled PLA materials using poplar trees

Bhagia

Lowden

Erdman

et al. 2020

Applied Materials Today

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Development of mesopores in superfine grain graphite neutron-irradiated at high fluence

Contescu¹,

Arregui-Mena²,

Campbell³

et al. 2019

Carbon

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Chemical and Morphological Structure of Transgenic Switchgrass Organosolv Lignin Extracted by Ethanol, Tetrahydrofuran, and γ-Valerolactone Pretreatments

Liang

Wang

Bhagia

et al. 2022

ACS Sustainable Chem. Eng.

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The recalcitrance of lignocellulosic biomass is a challenge in biological-based biorefinery systems due to the complex physicochemical structure of plant cell walls. Pretreatment and genetic modification are two approaches in biomass conversion that have succeeded in modifying the structure of lignocellulose to enable better enzymatic deconstruction. However, the structural differences among pretreatment-solubilized lignin isolated from switchgrass genotypes have not been extensively investigated. Here, three organosolv pretreatment systems�ethanol (EtOH), tetrahydrofuran (THF), and γ-valerolactone (GVL)�were used on wildtype (WT) and two transgenic switchgrasses. All organosolv pretreatments caused a significant reduction in the molecular mass of lignins; particularly, up to ∼90% decrease was observed in EtOH-pretreated lignin compared to untreated lignin. The WT EtOH lignin also presented the smallest particle size among all WT lignins. THF pretreated transgenic lignins showed a higher molecular mass, β-O-4 linkages, and aliphatic hydroxyl content compared to EtOH and GVL pretreated lignin. The number of hydrogen bonds between lignin and the organic solvents calculated from the molecular dynamics simulations followed the same trend as the experimentally determined reduction in lignin molecular mass. The results revealed the structural changes of solubilized lignin isolated from wild-type and transgenic switchgrass after different organosolv pretreatments.

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Sustainable Energy‐Storage Materials from Lignin–Graphene Nanocomposite‐Derived Porous Carbon Film

Tran

Keum

et al. 2017

Energy Tech

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A simple, green approach to fabricating porous free‐standing carbon films is presented. An alkaline solution of low‐cost, renewable lignin and graphene oxide (GO) is cast, followed by simultaneous carbonization and activation. Lignin, which is the least valued product from several biomass processing industries, is an efficient source of carbon when used as an intercalating agent to separate graphene sheets derived from homogeneous GO/lignin nanocomposite films prepared from an aqueous alkaline (KOH) solution. After thermal treatment the GO/lignin films show complete dispersion of reduced GO sheets within amorphous lignin‐derived carbon. The presence of KOH in the film produces activated carbon. These activated carbon films display a specific surface area of up to 1744 m2 g−1 and consist of a balance of pore volumes with pore sizes below and above 1 nm. A two‐electrode supercapacitor composed of these films in an aqueous electrolyte exhibits near‐ideal capacitive behavior at an ultrahigh scan rate of 1 V s−1, while maintaining an excellent specific capacitance of 162 F g−1. Such outstanding performance of renewable carbon as a supercapacitor, in addition to the ease of electrode fabrication from a precursor containing 85 % lignin, offers a novel method for valorization of lignin‐rich byproduct streams from biomass processing industries.

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Beyond the classical kinetic model for chronic graphite oxidation by moisture in high temperature gas-cooled reactors

Contescu

Mee

Lee

et al. 2018

Carbon

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Lignin-Derived Carbon Fibers as Efficient Heterogeneous Solid Acid Catalysts for Esterification of Oleic Acid

et al. 2018

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The production of biodiesel by the esterification of oleic acid, as an example of free fatty acid (FFA), was explored by using a new solid acid catalyst derived from lignin, a highly abundant low-cost biomass material. The catalyst was synthesized from lignin-derived carbon fiber by straightforward sulfonation and contains 1.86 mmol/g of sulfonic acid (-SO3H) groups. The catalyst was characterized by a variety of techniques including PXRD, TGA, TPD-MS, SEM, and XPS to understand the surface chemistry and the result of sulfonation. It was found that the sulfonated lignin-derived carbon fiber (CF-SO3H) catalyst was very efficient at esterifying oleic acid at 80 oC in 4 hours, with 10 wt. % catalyst (in terms of oleic acid content) and at a 10:1 molar ratio of methanol: oleic acid with a yield of 92%. Furthermore, the catalyst can be reused with no significant loss in activity after 4 cycles. Hence, synthesizing solid acid catalysts from lignin-derived carbon fiber affords a novel strategy for producing biodiesel via ‘green chemistry’.

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Progress Report on Graphite-Salt Intrusion Studies

Gallego

Contescu

Keiser

2020

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Nidia Gallego

Activated Carbons Derived from High-Temperature Pyrolysis of Lignocellulosic Biomass

Tensile properties of 3D-printed wood-filled PLA materials using poplar trees

Development of mesopores in superfine grain graphite neutron-irradiated at high fluence

Chemical and Morphological Structure of Transgenic Switchgrass Organosolv Lignin Extracted by Ethanol, Tetrahydrofuran, and γ-Valerolactone Pretreatments

Sustainable Energy‐Storage Materials from Lignin–Graphene Nanocomposite‐Derived Porous Carbon Film

Beyond the classical kinetic model for chronic graphite oxidation by moisture in high temperature gas-cooled reactors

Lignin-Derived Carbon Fibers as Efficient Heterogeneous Solid Acid Catalysts for Esterification of Oleic Acid

Progress Report on Graphite-Salt Intrusion Studies

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