[29] Dimensionally reduced machine learning model for predicting single component octanol–water partition coefficients.

Kenney, D. H.; Paffenroth, R. C.; Timko, M. T.; Teixeira, A. R., Dimensionally reduced machine learning model for predicting single component octanol–water partition coefficients. Journal of Cheminformatics 2023, 15 (1), 9.

[24] Integrated thermal reforming and electro-oxidation in ammonia-fueled tubular solid oxide fuel cells toward autothermal operation.

Jantakananuruk, N.; Page, J. R.; Armstrong, C. D.; Persky, J.; Datta, R.; Teixeira, A. R., Integrated thermal reforming and electro-oxidation in ammonia-fueled tubular solid oxide fuel cells toward autothermal operation. J. Power Sources (2022), 548, 231999.

[25] Dominance of heat transfer limitations in conventional sol-gel synthesis of LTA revealed by microcrystallization

Crislip, J.C., Vicens, J., Pham, T., Zhang, Y., Tompsett, G., Teixeira, A.R, Dominance of heat transfer limitations in conventional sol-gel synthesis of LTA revealed by microcrystallization. J Flow Chem, 2022, 12, 397–408.

[26] Elucidating the role of reactive nitrogen intermediates in hetero-cyclization during hydrothermal liquefaction of food waste

LeClerc, H. O; Atwi, R.; Niles, S. F.; Mckenna, A.; Timko, M. T.; West, H. W.; Teixeira, A. R, Elucidating the role of reactive nitrogen intermediates in hetero-cyclization during hydrothermal liquefaction of food waste. Green Chemistry, 2022, 24 (13), 5125-5141.

[27] Emergent Chemical Behavior in Mixed Food and Lignocellulosic Green Waste Hydrothermal Liquefaction.

LeClerc, H. O.; Page, J. R.; Tompsett, G. A.; Niles, S. F.; McKenna, A. M.; Valla, J. A.; Timko, M. T.; Teixeira, A. R., Emergent Chemical Behavior in Mixed Food and Lignocellulosic Green Waste Hydrothermal Liquefaction. ACS Sustainable Chemistry & Engineering 2022.

[28] Roadmap for Deployment of Modularized Hydrothermal Liquefaction: Understanding the Impacts of Industry Learning, Optimal Plant Scale, and Delivery Costs on Biofuel Pricing.

Shahabuddin, M.; Italiani, E.; Teixeira, A. R.; Kazantzis, N.; Timko, M. T., Roadmap for Deployment of Modularized Hydrothermal Liquefaction: Understanding the Impacts of Industry Learning, Optimal Plant Scale, and Delivery Costs on Biofuel Pricing. ACS Sustainable Chemistry & Engineering 2023, 11 (2), 733-743.

[29] Hydroxyapatite catalyzed hydrothermal liquefaction transforms food waste from an environmental liability to renewable fuel.

LeClerc, H. O.; Tompsett, G. A.; Paulsen, A. D.; McKenna, A. M.; Niles, S. F.; Reddy, C. M.; Nelson, R. K.; Cheng, F.; Teixeira, A. R.; Timko, M. T., Hydroxyapatite catalyzed hydrothermal liquefaction transforms food waste from an environmental liability to renewable fuel. iScience 2022, 25 (9), 104916.

It’s a blur of a year. We pretend this year did not happen.

[19] An automated flow platform for accurate determination of gas–liquid–solid reaction kinetics

X. Duan, J. Tu, A. R. Teixeira, L. Sang, K. F. Jensen, J .Zhang - Reaction Chemistry & Engineering, 2020

[20] Accessing multidimensional mixing via 3D printing and showerhead micromixer design

Zhang, H, Kopfmüller, T, Achermann, R, et al. Accessing multidimensional mixing via 3D printing and showerhead micromixer design. AIChE J. 2020; 66:e16873. https://doi.org/10.1002/aic.16873

[21] Advances in dynamically controlled catalytic reaction engineering

C. D. Armstrong, A. R. Teixeira, Advances in dynamically controlled catalytic reaction engineering. Reaction Chemistry & Engineering 5, 2185-2203 (2020).

[22] Identifying the roles of acid–base sites in formation pathways of tolualdehydes from acetaldehyde over MgO-based catalysts

M. Lusardi, T. Struble, A. R. Teixeira, K. F. Jensen, Identifying the roles of acid–base sites in formation pathways of tolualdehydes from acetaldehyde over MgO-based catalysts. Catalysis Science & Technology 10, 536-548 (2020).

[23] termination of fast gas–liquid reaction kinetics in flow

J. Zhang, A. R. Teixeira, H. Zhang, K. F. Jensen, Determination of fast gas–liquid reaction kinetics in flow. Reaction Chemistry & Engineering 5, 51-57 (2020).

[17] Flow Toolkit for Measuring Gas Diffusivity in Liquids

Zhang, J; Teixeira A. R.; Zhang, J; Jensen, K. F., Flow Toolkit for Measuring Gas Diffusivity in Liquids, Analytical Chemistry 2019, 91 (6), 4004-4009.

[18] Enabling low power acoustics for capillary sonoreactors

Navarro-Brull, F. J.; Teixeira, A. R.; Giri, G.; Gómeza, R, Enabling low power acoustics for capillary sonoreactors, Ultrasonics Sonochemistry, 2019, 56, 105-113.

[14] Automated measurements of gas‐liquid mass transfer in micropacked bed reactors

Zhang, J.; Teixeira, A. R.; Jensen, K. F., Automated measurements of gas-liquid mass transfer in micropacked bed reactors. AlChE J. 2018, 64 (2), 564-570.

[15] Catalytic hydrogenation of N-4-nitrophenyl nicotinamide in a micro-packed bed reactor

Yang, C.; Teixeira, A. R.; Shi, Y.; Born, S. C.; Lin, H.; Li Song, Y.; Martin, B.; Schenkel, B.; Peer Lachegurabi, M.; Jensen, K. F., Catalytic hydrogenation of N-4-nitrophenyl nicotinamide in a micro-packed bed reactor. Green Chem. 2018.

[16] Reduction of Dispersion in Ultrasonically-Enhanced Micropacked Beds

Navarro-Brull, F. J.; Teixeira, A. R.; Zhang, J.; Gómez, R.; Jensen, K. F., Reduction of Dispersion in Ultrasonically-Enhanced Micropacked Beds. Industrial & Engineering Chemistry Research 2018, 57 (1), 122-128.

[11] Hydrodynamics of Gas‐Liquid Flow in Micro‐Packed Beds: Pressure Drop, Liquid Holdup and Two‐Phase Model

Zhang, J.; Teixeira, A. R.; Kögl, L. T.; Yang, L.; Jensen, K. F., Hydrodynamics of Gas‐Liquid Flow in Micro‐Packed Beds: Pressure Drop, Liquid Holdup and Two‐Phase Model. AlChE J. 2017.

[12] Design and Scaling Up of Microchemical Systems: A Review

Zhang, J.; Wang, K.; Teixeira, A. R.; Jensen, K. F.; Luo, G., Design and Scaling Up of Microchemical Systems: A Review. Annual Review of Chemical and Biomolecular Engineering 2017, 8 (1), 285-305.

[13] Automated in Situ Measurement of Gas Solubility in Liquids with a Simple Tube-in-Tube Reactor

Zhang, J.; Teixeira, A. R.; Zhang, H.; Jensen, K. F., Automated in situ Measurement of Gas Solubility in Liquids with a Simple Tube-in-Tube Reactor. Anal. Chem. 2017.

[10] Spontaneous aerosol ejection: origin of inorganic particles in biomass pyrolysis

Teixeira, A. R.; Gantt, R.; Joseph, K. E.; Maduskar, S.; Paulsen, A. D.; Krumm, C.; Zhu, C.; Dauenhauer, P. J., Spontaneous Aerosol Ejection: Origin of Inorganic Particles in Biomass Pyrolysis. ChemSusChem 2016, 9 (11), 1322-1328.

[7] Quantitative carbon detector (QCD) for calibration-free, high-resolution characterization of complex mixtures

Maduskar, S.; Teixeira, A. R.; Paulsen, A. D.; Krumm, C.; Mountziaris, T. J.; Fan, W.; Dauenhauer, P. J., Quantitative carbon detector (QCD) for calibration-free, high-resolution characterization of complex mixtures. Lab on a Chip 2015, 15 (2), 440-447.

[8] Reactive liftoff of crystalline cellulose particles

Teixeira, A. R.; Krumm, C.; Vinter, K. P.; Paulsen, A. D.; Zhu, C.; Maduskar, S.; Joseph, K. E.; Greco, K.; Stelatto, M.; Davis, E.; Vincent, B.; Hermann, R.; Suszynski, W.; Schmidt, L. D.; Fan, W.; Rothstein, J. P.; Dauenhauer, P. J., Reactive Liftoff of Crystalline Cellulose Particles. Scientific Reports 2015, 5, 11238.

[9] 2D surface structures in small zeolite MFI crystals

Teixeira, A. R.; Qi, X.; Conner, W. C.; Mountziaris, T. J.; Fan, W.; Dauenhauer, P. J., 2D Surface Structures in Small Zeolite MFI Crystals. Chem. Mater. 2015, 27 (13), 4650-4660.

[5] Fast pyrolysis of wood for biofuels: spatiotemporally resolved diffuse reflectance in situ spectroscopy of particles

Paulsen, A. D.; Hough, B. R.; Williams, C. L.; Teixeira, A. R.; Schwartz, D. T.; Pfaendtner, J.; Dauenhauer, P. J., Fast Pyrolysis of Wood for Biofuels: Spatiotemporally Resolved Diffuse Reflectance In situ Spectroscopy of Particles. ChemSusChem 2014, 7 (3), 765-776.

[6] On asymmetric surface barriers in MFI zeolites revealed by frequency response

Teixeira, A. R.; Qi, X.; Chang, C.-C.; Fan, W.; Conner, W. C.; Dauenhauer, P. J., On Asymmetric Surface Barriers in MFI Zeolites Revealed by Frequency Response. J. Phys. Chem. C 2014, 118 (38), 22166-22180.

[2] Microexplosions in the upgrading of biomass-derived pyrolysis oils and the effects of simple fuel processing

Teixeira, A. R.; Hermann, R. J.; Kruger, J. S.; Suszynski, W. J.; Schmidt, L. D.; Schmidt, D. P.; Dauenhauer, P. J., Microexplosions in the Upgrading of Biomass-Derived Pyrolysis Oils and the Effects of Simple Fuel Processing. ACS Sustainable Chemistry & Engineering 2013, 1 (3), 341-348.

[3] Enhanced molecular transport in hierarchical silicalite-1

Chang, C.-C.; Teixeira, A. R.; Li, C.; Dauenhauer, P. J.; Fan, W., Enhanced Molecular Transport in Hierarchical Silicalite-1. Langmuir 2013, 29 (45), 13943-13950.

[4] Dominance of surface barriers in molecular transport through silicalite-1

Teixeira, A. R.; Chang, C.-C.; Coogan, T.; Kendall, R.; Fan, W.; Dauenhauer, P. J., Dominance of Surface Barriers in Molecular Transport through Silicalite-1. J. Phys. Chem. C 2013, 117 (48), 25545-25555.

[1] Aerosol generation by reactive boiling ejection of molten cellulose

Teixeira, A. R.; Mooney, K. G.; Kruger, J. S.; Williams, C. L.; Suszynski, W. J.; Schmidt, L. D.; Schmidt, D. P.; Dauenhauer, P. J., Aerosol generation by reactive boiling ejection of molten cellulose. Energy & Environmental Science 2011, 4 (10), 4306-4321.