Your search keyword '"Andrew R. Teixeira"' showing total 3 results

1. Spontaneous Aerosol Ejection: Origin of Inorganic Particles in Biomass Pyrolysis

Author

Andrew R. Teixeira, Cheng Zhu, Alex D. Paulsen, Saurabh Maduskar, Kristeen E. Joseph, Rachel Gantt, Christoph Krumm, and Paul J. Dauenhauer

Subjects

Materials science, 020209 energy, General Chemical Engineering, Inorganic chemistry, Lignocellulosic biomass, Biomass, 02 engineering and technology, chemistry.chemical_compound, Boiling, 0202 electrical engineering, electronic engineering, information engineering, Environmental Chemistry, General Materials Science, Particle Size, Cellulose, Aerosols, Volatilisation, Temperature, 021001 nanoscience & nanotechnology, Aerosol, General Energy, chemistry, Inorganic Chemicals, Particle size, Volatilization, 0210 nano-technology, Pyrolysis

Abstract

At high thermal flux and temperatures of approximately 500 °C, lignocellulosic biomass transforms to a reactive liquid intermediate before evaporating to condensable bio-oil for downstream upgrading to renewable fuels and chemicals. However, the existence of a fraction of nonvolatile compounds in condensed bio-oil diminishes the product quality and, in the case of inorganic materials, catalyzes undesirable aging reactions within bio-oil. In this study, ablative pyrolysis of crystalline cellulose was evaluated, with and without doped calcium, for the generation of inorganic-transporting aerosols by reactive boiling ejection from liquid intermediate cellulose. Aerosols were characterized by laser diffraction light scattering, inductively coupled plasma spectroscopy, and high-speed photography. Pyrolysis product fractionation revealed that approximately 3 % of the initial feed (both organic and inorganic) was transported to the gas phase as aerosols. Large bubble-to-aerosol size ratios and visualization of significant late-time ejections in the pyrolyzing cellulose suggest the formation of film bubbles in addition to the previously discovered jet formation mechanism.

Published

2016

2. Fast Pyrolysis of Wood for Biofuels: Spatiotemporally Resolved Diffuse Reflectance In situ Spectroscopy of Particles

Author

Blake R. Hough, Jim Pfaendtner, Daniel T. Schwartz, Alex D. Paulsen, C. Luke Williams, Paul J. Dauenhauer, and Andrew R. Teixeira

Subjects

Materials science, business.industry, General Chemical Engineering, Biomass, Decomposition, Diesel fuel, General Energy, Biofuel, Scientific method, Environmental Chemistry, Particle, Organic chemistry, General Materials Science, Gasoline, Process engineering, business, Pyrolysis

Abstract

Fast pyrolysis of woody biomass is a promising process capable of producing renewable transportation fuels to replace gasoline, diesel, and chemicals currently derived from nonrenewable sources. However, biomass pyrolysis is not yet economically viable and requires significant optimization before it can contribute to the existing oil-based transportation system. One method of optimization uses detailed kinetic models for predicting the products of biomass fast pyrolysis, which serve as the basis for the design of pyrolysis reactors capable of producing the highest value products. The goal of this work is to improve upon current pyrolysis models, usually derived from experiments with low heating rates and temperatures, by developing models that account for both transport and pyrolysis decomposition kinetics at high heating rates and high temperatures (>400 °C). A new experimental technique is proposed herein: spatiotemporally resolved diffuse reflectance in situ spectroscopy of particles (STR-DRiSP), which is capable of measuring biomass composition during fast pyrolysis with high spatial (10 μm) and temporal (1 ms) resolution. Compositional data were compared with a comprehensive 2D single-particle model, which incorporated a multistep, semiglobal reaction mechanism, prescribed particle shrinkage, and thermophysical properties that varied with temperature, composition, and orientation. The STR-DRiSP technique can be used to determine the transport-limited kinetic parameters of biomass decomposition for a wide variety of biomass feedstocks.

Published

2013

3. Inside Cover Picture: Fast Pyrolysis of Wood for Biofuels: Spatiotemporally Resolved Diffuse Reflectance In situ Spectroscopy of Particles (ChemSusChem 3/2014)

Author

Jim Pfaendtner, Daniel T. Schwartz, Andrew R. Teixeira, Alex D. Paulsen, Blake R. Hough, Paul J. Dauenhauer, and C. Luke Williams

Subjects

Reaction mechanism, Materials science, General Chemical Engineering, Biomass, In situ spectroscopy, General Energy, Chemical engineering, Biofuel, Environmental Chemistry, Organic chemistry, General Materials Science, Cover (algebra), Diffuse reflection, Pyrolysis

Published

2014