Jill R. Jensen scite author profile

The kinetics of dilute acid hydrolysis for aspen, balsam, and switchgrass were investigated at various temperatures, acid concentrations, and reaction times using small-scale isothermal tubular reactors. The experimental data was fitted to a four-step kinetic model with first-order irreversible rate constants at each step. The maximum yields of xylose monomer for aspen and balsam show limited variability with changing reaction severity with maximum levels of approximately 85% and 67% of initial xylan, respectively. Switchgrass xylose monomer yields varied significantly with very low yields observed at 0.25 wt % acid (32% of initial xylan) and relatively high yields at 0.75 wt % acid (81% of initial xylan). The measured furfural levels at the point where xylose monomer is maximized, relative to initial xylan, range from 1% to 6% for aspen and balsam, and 3% to 15% for switchgrass. Excellent agreement, both quantitatively and qualitatively, is shown between the experimental monomer data and its model fit. Although the maximum xylose oligomer concentrations and the initial concentrations during oligomer formation are accurately predicted, the model with irreversible kinetic constants does not describe the oligomer data accurately at long times. The model predicts furfural levels comparable to those measured; however, the model overpredicts early data points and underpredicts late data points. Arrhenius kinetic parameters were derived for all three species at each step of the proposed model and these parameters were of the same order as literature values. Preliminary results in regards to the effect of aspen solids loading on reaction kinetics show that a 50% decrease in solids loading (10% to 5%) results in faster rates of reaction. This is particularly apparent for the degradation of xylose monomer which increases by a factor of almost 3. Several recommendations to improve the modeling of dilute acid hydrolysis reactions are discussed.

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Effects of dilute acid pretreatment conditions on enzymatic hydrolysis monomer and oligomer sugar yields for aspen, balsam, and switchgrass

Jensen¹,

Morinelly²,

Gossen³

et al. 2010

Bioresource Technology

107

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Kinetic characterization of biomass dilute sulfuric acid hydrolysis: Mixtures of hardwoods, softwood, and switchgrass

et al. 2008

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in Wiley InterScience (www.interscience.wiley.com).The effects of woody biomass mixtures were investigated on the rates of hemicellulose hydrolysis by dilute acid. Very good agreement between the model predictions and single species acid hydrolysis data confirmed the validity of a pseudo first-order model approach. This model was then utilized to predict monomer sugar concentrations for mixtures of hardwood (aspen, basswood, and red maple), a softwood (balsam), and the energy crop switchgrass, with very good agreement. The results of this study show that there are not significant synergistic or antagonistic effects by mixtures of woody biomass species on the kinetics of hemicellulose hydrolysis by dilute acid. Kinetic parameters were developed for each woody biomass species with xylose formation activation energies ranging from 76.19-171.20 kJ/mol, and pre-exponential factors ranging from 2.19 3 10 8 -7.73 3 10 19 min 21 . Overall xylose yields for pure biomass species ranged from approximately 66-88% with balsam having the lowest yield and switchgrass producing the highest yield.

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Ethanol from lignocellulosics, U.S. federal energy and agricultural policy, and the diffusion of innovation

Jensen

Halvorsen

Shonnard

2011

Biomass and Bioenergy

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Jill R. Jensen

Kinetic Characterization of Xylose Monomer and Oligomer Concentrations during Dilute Acid Pretreatment of Lignocellulosic Biomass from Forests and Switchgrass

Effects of dilute acid pretreatment conditions on enzymatic hydrolysis monomer and oligomer sugar yields for aspen, balsam, and switchgrass

Kinetic characterization of biomass dilute sulfuric acid hydrolysis: Mixtures of hardwoods, softwood, and switchgrass

Ethanol from lignocellulosics, U.S. federal energy and agricultural policy, and the diffusion of innovation

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