Search

Your search keyword '"Derek R. Vardon"' showing total 46 results
Start Over Author "Derek R. Vardon" Language undetermined
46 results on '"Derek R. Vardon"'

4. Toward low-cost biological and hybrid biological/catalytic conversion of cellulosic biomass to fuels

Author

Lee R. Lynd, Gregg T. Beckham, Adam M. Guss, Lahiru N. Jayakody, Eric M. Karp, Costas Maranas, Robert L. McCormick, Daniel Amador-Noguez, Yannick J. Bomble, Brian H. Davison, Charles Foster, Michael E. Himmel, Evert K. Holwerda, Mark S. Laser, Chiam Yu Ng, Daniel G. Olson, Yuriy Román-Leshkov, Cong T. Trinh, Gerald A. Tuskan, Vikas Upadhayay, Derek R. Vardon, Lin Wang, and Charles E. Wyman

Subjects
Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Environmental Chemistry, Pollution
Abstract

Hybrid processes, featuring biological conversion of lignocellulose to small molecules followed by chemo-catalytic conversion to larger molecules suitable for difficult-to-electrify transport modes, are a promising route to biomass-derived fuels in demand for climate stabilization.

Published
2022
Full Text
View/download PDF

5. Atomic Layer Deposition with TiO2 for Enhanced Reactivity and Stability of Aromatic Hydrogenation Catalysts

Author

Carrie A. Farberow, W. Wilson McNeary, Karen Buechler, Kurt M. Van Allsburg, Kinga A. Unocic, Evan C. Wegener, Derek R. Vardon, Tugce Eralp Erden, Gabriella D. Lahti, Davis R. Conklin, Watson Michael John, Staci Moulton, Sean A. Tacey, Michael B. Griffin, Jessica Burger, Chris Gump, Luke Tuxworth, Eric C. D. Tan, and Arrelaine A. Dameron

Subjects
Atomic layer deposition, Materials science, Chemical engineering, Reactivity (chemistry), General Chemistry, Catalysis
Published
2021
Full Text
View/download PDF

6. Towards improved conversion of wet waste to jet fuel with atomic layer deposition-coated hydrodeoxygenation catalysts

Author

W. Wilson McNeary, Jacob H. Miller, Sean A. Tacey, Jonathan Travis, Gabriella D. Lahti, Michael B. Griffin, Katherine L. Jungjohann, Glenn Teeter, Tugce Eralp Erden, Carrie A. Farberow, Luke Tuxworth, Michael J. Watson, Arrelaine A. Dameron, and Derek R. Vardon

Subjects
General Chemical Engineering, Environmental Chemistry, General Chemistry, Industrial and Manufacturing Engineering
Published
2023
Full Text
View/download PDF

7. Experimental and computational studies of the production of 1,3-butadiene from 2,3-butanediol using SiO2-supported H3PO4 derivatives

Author

Juan Vicente Alegre Requena, Glenn R. Hafenstine, Xiangchen Huo, Yanfei Guan, Jim Stunkel, Frederick G. Baddour, Kinga A. Unocic, Bruno C. Klein, Ryan E. Davis, Robert S. Paton, Derek R. Vardon, and Seonah Kim

Subjects
General Chemical Engineering, Environmental Chemistry, General Chemistry, Industrial and Manufacturing Engineering
Abstract

Silica-supported phosphoric acid and metal phosphate catalyzed 1,3-butadiene (BDE) production from 2,3-butanediol (2,3-BDO) was studied using experimental and computational techniques. The catalyst was initially tested in a continuous flow reactor using commercially available 2,3-BDO, leading to maximum BDE yields of 63 C%. Quantum chemical mechanistic studies revealed 1,2-epoxybutane is a kinetically viable and thermodynamically stable intermediate, supported by experimental demonstration that this epoxide can be converted to BDE under standard reaction conditions. Newly proposed E2 and SN2’ elementary steps were studied to rationalize the formation of BDE and all detected side-products. Additionally, using QM/MM (ONIOM) calculations, we modeled silica-supported phosphate catalysts to study the effect of the alkali metal center. Natural population analysis showed that phosphate oxygen atoms are more negatively charged in CsH2PO4/SiO2 than in H3PO4/SiO2. In combination with temperature-programmed desorption experiments using CO2, the results of this study suggest that the improved selectivity achieved when adding the metal center is related to an increase in the basicity of the catalyst.

Published
2023
Full Text
View/download PDF

9. Vapor-phase conversion of aqueous 3-hydroxybutyric acid and crotonic acid to propylene over solid acid catalysts

Author

Timothy J. Strathmann, Gabriella D. Lahti, Yalin Li, Shijie Leow, Derek R. Vardon, Lauren E. Cronmiller, Xiangchen Huo, Andrew J. Koehler, and Glenn R. Hafenstine

Subjects
chemistry.chemical_classification, Decarboxylation, technology, industry, and agriculture, Acetaldehyde, Raw material, Phosphate, complex mixtures, Catalysis, chemistry.chemical_compound, Acetic acid, Hydrocarbon, chemistry, Organic chemistry, 3-Hydroxybutyric Acid
Abstract

Diverse sources of wastewater organic carbon can be microbially funneled into biopolymers like polyhydroxybutyrate (PHB) that can be further valorized by conversion to hydrocarbon fuels and industrial chemicals. We report the vapor-phase dehydration and decarboxylation of PHB-derived monomer acids, 3-hydroxybutyric acid (3HB) and crotonic acid (CA), in water to propylene over solid acid catalysts using a packed-bed continuous-flow reactor. Propylene yields increase with increased Bronsted acidity of catalysts, with amorphous silica–alumina and niobium phosphate yielding 52 and 60 %C (percent feedstock carbon, max 75 %C) of feedstock 3HB and CA, respectively; additional products include CO2 and retro-aldol products (acetaldehyde and acetic acid). Deactivation studies indicate progressive and permanent steam deactivation of amorphous silica–alumina, while re-calcination partially recovers niobium phosphate activity. Experiments demonstrating sustained reactor operation over niobium phosphate provide a promising technology pathway for increasing valorization of organic-rich wastewater.

Published
2021
Full Text
View/download PDF

10. Screening and evaluation of biomass upgrading strategies for sustainable transportation fuel production with biomass-derived volatile fatty acids

Author

Jacob H. Miller, Stephen M. Tifft, Matthew R. Wiatrowski, Pahola Thathiana Benavides, Nabila A. Huq, Earl D. Christensen, Teresa Alleman, Cameron Hays, Jon Luecke, Colin M. Kneucker, Stefan J. Haugen, Violeta Sànchez i Nogué, Eric M. Karp, Troy R. Hawkins, Avantika Singh, and Derek R. Vardon

Subjects
Multidisciplinary
Abstract

Biomass conversion to fuels and chemicals is crucial to decarbonization, but choosing an advantageous upgrading pathway out of many options is challenging. Rigorously evaluating all candidate pathways (process simulation, product property testing) requires a prohibitive amount of research effort; even simple upgrading schemes have hundreds of possible permutations. We present a method enabling high-throughput screening by approximating upgrading unit operations and drop-in compatibility of products (

Published
2022
Full Text
View/download PDF

11. Single-phase catalysis for reductive etherification of diesel bioblendstocks

Author

Matthew R. Wiatrowski, Qianying Guo, Derek R. Vardon, Glenn R. Hafenstine, Xiangchen Huo, Nabila A. Huq, Davis R. Conklin, and Kinga A. Unocic

Subjects
chemistry.chemical_compound, chemistry, Catalyst support, Inorganic chemistry, Batch reactor, Oxide, Environmental Chemistry, Ether, Selectivity, Pollution, Cetane number, Catalysis, Space velocity
Abstract

Reductive etherification is a promising catalytic chemistry for coupling biomass derived alcohols and ketones to produce branched ethers that can be used as high cetane, low sooting blendstocks for diesel fuel applications. Previous catalyst materials examined for reductive etherification have typically been limited to binary physical mixtures of metal hydrogenation and acidic acetalization catalysts with limited thermal stability and industrial applicability. To address this, we developed a single-phase catalyst comprising Pd supported on acidic metal oxides with high catalytic activity, product selectivity, and regeneration stability. Batch reactor screening identified niobium phosphate (NbOPO4) as the most active acidic metal oxide catalyst support, which was downselected to synthesize single-phase catalysts by Pd loading. Several branched ethers with favourable fuel properties were synthesized to demonstrate broad catalyst applicability. The fresh Pd/NbOPO4 catalyst displayed a surface area of 130 m2 g−1, high acidity of 324 μmol g−1 and Pd dispersion of 7.8%. The use of acidic metal oxide support allowed for elevated reaction temperatures with a mass selectivity to 4-butoxyheptane of 81% at 190 °C and an apparent activation energy of 40 kJ mol−1. Continuous flow reactor testing demonstrated steady catalyst deactivation due to coke formation of 10 wt% after 117 h of time-on-stream. Four simulated catalyst regeneration cycles led to small changes in surface area and total acidity; however, a decrease in Pd site density from 18 to 8 μmol g−1, in combination with an apparent Pd nanoparticle size effect, caused an increase in the production rate of 4-butoxyheptane from 138 to 190 μmol gcat−1 min−1 with the regenerated catalyst. Lastly, technoeconomic analysis showed that higher H2 equivalents and lower weight hourly space velocity values can reduce ether catalytic production costs.

Published
2020
Full Text
View/download PDF

12. Inverse Bimetallic RuSn Catalyst for Selective Carboxylic Acid Reduction

Author

Evan C. Wegener, Todd R. Eaton, Vassili Vorotnikov, Amy E. Settle, Gregg T. Beckham, Derek R. Vardon, Kellene A. Orton, Jeffrey T. Miller, and Ce Yang

Subjects
chemistry.chemical_classification, 010405 organic chemistry, Carboxylic acid, Inverse, chemistry.chemical_element, General Chemistry, 010402 general chemistry, Tin oxide, 01 natural sciences, Combinatorial chemistry, Catalysis, 0104 chemical sciences, Ruthenium, chemistry.chemical_compound, 1-Propanol, chemistry, Reactivity (chemistry), skin and connective tissue diseases, Bimetallic strip
Abstract

Inverse bimetallic catalysts (IBCs), synthesized by sequential deposition of noble and oxophilic metals, offer potential reactivity enhancements to various reactions, including the reduction of car...

Published
2019
Full Text
View/download PDF

13. Enhanced Catalyst Durability for Bio-Based Adipic Acid Production by Atomic Layer Deposition

Author

Karthikeyan K. Ramasamy, Ryon W. Tracy, Amy E. Settle, Reuben Sarkar, Watson Michael John, Katherine E. Hurst, Ryan M. Richards, Michael B. Griffin, Derek R. Vardon, Arrelaine A. Dameron, Davis R. Conklin, Xiangchen Huo, Gregg T. Beckham, Arun Devaraj, Kinga A. Unocic, Eric C. D. Tan, Nicholas S. Cleveland, Allyson M. York, Carrie A. Farberow, Steven T. Christensen, and Elizabeth J. Kautz

Subjects
endocrine system, Muconic acid, Adipic acid, Materials science, endocrine system diseases, Oxide, 02 engineering and technology, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Atomic layer deposition, General Energy, chemistry, Chemical engineering, Coating, engineering, Thermal stability, Leaching (metallurgy), 0210 nano-technology
Abstract

Summary Atomic layer deposition (ALD) improves the durability of metal catalysts using nanoscale metal oxide coatings. However, targeted coating strategies and economic models are lacking for process-specific deactivation challenges that account for implications at scale. Herein, we apply Al2O3 ALD to Pd/TiO2 to increase durability during hydrogenation of muconic acid, a bio-based platform chemical, to adipic acid. Initial coating development and characterization are performed on the milligram scale using stop-flow ALD. Subsequently, ALD coating scale is increased by 3 orders of magnitude using fluidized bed ALD. Activity, leaching resistance, and thermal stability are evaluated at each synthesis scale. ALD-coated catalysts retain up to 2-fold greater muconic acid hydrogenation activity and undergo significantly less physical restructuring than uncoated Pd/TiO2 after high-temperature treatments, while reducing Pd leaching by over 4-fold. Techno-economic analysis for an adipic acid biorefinery supports increased ALD material costs through catalyst lifetime extension, underscoring the potential viability of this technology.

Published
2019
Full Text
View/download PDF

14. Innovative Chemicals and Materials from Bacterial Aromatic Catabolic Pathways

Author

Peter C. St. John, Nicholas S. Cleveland, Graham Dominick, Priyanka Singh, William E. Michener, Davinia Salvachúa, Xiunan Yi, Brenna A. Black, Derek R. Vardon, Kelsey J. Ramirez, Chelsea R. Martinez, Adam M. Guss, A. Nolan Wilson, Gregg T. Beckham, Nicholas J. Grundl, Todd A. VanderWall, Nicholas A. Rorrer, Christopher W. Johnson, Payal Khanna, Joshua R. Elmore, Darren J. Peterson, Mary J. Biddy, and Yannick J. Bomble

Subjects
Muconic acid, biology, Catabolism, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, biology.organism_classification, 01 natural sciences, Decomposition, Combinatorial chemistry, Pseudomonas putida, 0104 chemical sciences, Metabolic pathway, chemistry.chemical_compound, General Energy, Petrochemical, chemistry, Bioreactor, Molecule, 0210 nano-technology
Abstract

Summary To drive innovation in chemical and material applications beyond what has been afforded by the mature petrochemical industry, new molecules that possess diverse chemical functionality are needed. One source of such molecules lies in the varied metabolic pathways that soil microbes utilize to catabolize aromatic compounds generated during plant decomposition. Here, we have engineered Pseudomonas putida KT2440 to convert these aromatic compounds to 15 catabolic intermediates that exhibit substantial chemical diversity. Bioreactor cultivations, analytical methods, and bench-scale separations were developed to enable production (up to 58 g/L), detection, and purification of each target molecule. We further engineered strains for production of a subset of these molecules from glucose, achieving a 41% molar yield of muconic acid. Finally, we produce materials from three compounds to illustrate the potential for realizing performance-advantaged properties relative to petroleum-derived analogs.

Published
2019
Full Text
View/download PDF

15. Top 13 Blendstocks Derived from Biomass for Mixing-Controlled Compression-Ignition (Diesel) Engines: Bioblendstocks with Potential for Decreased Emissions and Improved Operability

Author

Ethan Oksen, Greg Zaimes, Andrew J. Schmidt, Gina M. Fioroni, Pahola T. Benavides, Robert L. McCormick, Sibendu Som, Eric J. Sundstrom, Jonathan Burton, Nicholas Carlson, Daniel A. Ruddy, Charles J. Mueller, Troy R. Hawkins, Vanessa Dagle, Anthe George, Ryan W. Davis, Yunhua Zhu, Michael D. Kass, Daniel J. Gaspar, Alexander Landera, Evgueni Polikarpov, Derek R. Vardon, Andrew D Sutton, Matthew R. Wiatrowski, Andrew Bartling, Steven D. Phillips, Cameron M. Moore, Avantika Singh, Michael Talmadge, Jonathan Martin, Michael R. Thorson, Richard T. Hallen, Yuan Jiang, Hao Cai, Martha A. Arellano-Treviño, Joseph S. Carlson, Longwen Ou, Lelia Cosimbescu, Karthikeyan K. Ramasamy, Gina M. Magnotti, Teresa L. Alleman, Nabila A. Huq, Eric Monroe, and Lesley J. Snowden-Swan

Subjects
Ignition system, Diesel fuel, Operability, business.industry, law, Environmental science, Biomass, Process engineering, business, Compression (physics), Mixing (physics), law.invention
Published
2021
Full Text
View/download PDF

16. Correction: Adipic acid production from lignin

Author

Derek R. Vardon, Mary Ann Franden, Christopher W. Johnson, Eric M. Karp, Michael T. Guarnieri, Jeffrey G. Linger, Michael J. Salm, Timothy J. Strathmann, and Gregg T. Beckham

Subjects
Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Environmental Chemistry, Pollution
Abstract

Correction for ‘Adipic acid production from lignin’ by Derek R. Vardon et al., Energy Environ. Sci., 2015, 8, 617–628, https://doi.org/10.1039/C4EE03230F.

Published
2022
Full Text
View/download PDF

17. Tailoring diesel bioblendstock from integrated catalytic upgrading of carboxylic acids: a 'fuel property first' approach

Author

Robert S. Nelson, Jon Luecke, Charles S. McEnally, Earl Christensen, Seonah Kim, Derek R. Vardon, Amy E. Settle, Robert L. McCormick, Nicholas S. Cleveland, Lisa Fouts, Xiangchen Huo, Lisa D. Pfefferle, Nabila A. Huq, J. Hunter Mack, Jim Stunkel, Timothy J. Strathmann, Patrick A. Cherry, Peter C. St. John, Davinia Salvachúa, David G. Brandner, Anne K. Starace, Allyson M. York, and Gregg T. Beckham

Subjects
chemistry.chemical_classification, 010405 organic chemistry, Chemistry, Lignocellulosic biomass, Autoignition temperature, Renewable fuels, Raw material, 010402 general chemistry, 01 natural sciences, Pollution, 0104 chemical sciences, Diesel fuel, Hydrocarbon, Chemical engineering, Environmental Chemistry, Cetane number, Hydrodeoxygenation
Abstract

Lignocellulosic biomass offers the potential to produce renewable fuels at a scale commensurate with petroleum consumption. Hybrid approaches that combine biological and chemocatalytic processes have garnered increasing attention due to their flexibility for feedstock utilization and diversity of potential products. Of note, lignocellulosic sugars can be converted biologically to short-chain carboxylic acids, while subsequent chemocatalytic upgrading can elongate the carbon backbone and remove oxygen from the structure to produce drop-in hydrocarbon fuels. However, hybrid conversion processes are typically not designed with the fuel properties in mind a priori. In this work, we apply a “fuel property first” design approach to produce a tailored hydrocarbon bioblendstock with lower intrinsic sooting and drop-in diesel fuel potential. Initially, model predictions for six fuel properties critical to diesel applications (physicochemical requirements, energy content, safety considerations, autoignition ability, and sooting tendency) were used to screen an array of hydrocarbons accessible from upgrading individual and mixed C2/C4 acids. This screening step allowed for down-selection to a non-cyclic branched C14 hydrocarbon (5-ethyl-4-propylnonane) that can be synthesized from butyric acid through sequential catalytic reactions of acid ketonization, ketone condensation, and hydrodeoxygenation. Following evaluation of each conversion step with model compounds, butyric acid was then converted through an integrated catalytic process scheme to achieve >80% overall carbon yield to a hydrocarbon mixture product containing >60% of the target C14 hydrocarbon. The potential of this conversion strategy to produce a hydrocarbon diesel bioblendstock from lignocellulosic biomass was then demonstrated using corn stover-derived butyric acid produced from Clostridium butyricum fermentation. Experimental fuel property testing of the purified C14 blendstock validated the majority of the fuel property model predictions, including

Published
2019
Full Text
View/download PDF

19. Iodine‐Catalyzed Isomerization of Dimethyl Muconate

Author

Shuting Zhang, Ryan M. Richards, Michael F. Crowley, Derek R. Vardon, Amy E. Settle, Gregg T. Beckham, Nicholas A. Rorrer, Haiming Hu, and Laura Berstis

Subjects
Muconic acid, Dimethyl terephthalate, Reaction mechanism, 010405 organic chemistry, General Chemical Engineering, 010402 general chemistry, 01 natural sciences, Cycloaddition, 0104 chemical sciences, Catalysis, Solvent, chemistry.chemical_compound, General Energy, chemistry, Computational chemistry, Environmental Chemistry, General Materials Science, Dehydrogenation, Isomerization
Abstract

cis,cis-Muconic acid is a platform bio-based chemical that can be upgraded to drop-in commodity and novel monomers. Among the possible drop-in products, dimethyl terephthalate can be synthesized via esterification, isomerization, Diels-Alder cycloaddition, and dehydrogenation. The isomerization of cis,cis-dimethyl muconate (ccDMM) to the trans,trans-form (ttDMM) can be catalyzed by iodine; however, studies have yet to address (i) the mechanism and reaction barriers unique to DMM, and (ii) the influence of solvent, potential for catalyst recycle, and recovery of high-purity ttDMM. To address this gap, we apply a joint computational and experimental approach to investigate iodine-catalyzed isomerization of DMM. Density functional theory calculations identified unique regiochemical considerations owing to the large number of halogen-diene coordination schemes. Both transition state theory and experiments estimate significant barrier reductions with photodissociated iodine. Solvent selection was critical for rapid kinetics, likely because of solvent complexation with iodine. Under select conditions, ttDMM yields of 95 % were achieved in1 h with methanol, followed by high purity recovery (98 %) with crystallization. Lastly, post-reaction iodine can be recovered and recycled with minimal loss of activity. Overall, these findings provide new insight into the mechanism and conditions necessary for DMM isomerization with iodine to advance the state-of-the-art for bio-based chemicals.

Published
2018
Full Text
View/download PDF

20. Supercritical Methanol Solvolysis and Catalysis for the Conversion of Delignified Woody Biomass into Light Alcohol Gasoline Bioblendstock

Author

Hannah Nguyen, Nabila A. Huq, Daniela Stück, Stephen M. Tifft, Davis R. Conklin, Andrew J. Koehler, William Wilson McNeary, Gina M. Fioroni, Cameron Hays, Earl D. Christensen, Ian McNamara, Andrew Bartling, Ryan Davis, Kinga A. Unocic, and Derek R. Vardon

Subjects
Renewable Energy, Sustainability and the Environment, General Environmental Science
Published
2022
Full Text
View/download PDF

21. Catalytic activity and water stability of the MgO(111) surface for 2-pentanone condensation

Author

Derek R. Vardon, Xiangchen Huo, Davis R. Conklin, Vassili Vorotnikov, Ryan M. Richards, Raiven I. Balderas, Katharine Page, Kinga A. Unocic, Rajeev S. Assary, Mingxia Zhou, Zhenglong Li, and Stephen C. Purdy

Subjects
Process Chemistry and Technology, 2-Pentanone, Condensation, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Catalysis, 0104 chemical sciences, Nanomaterials, Metal, chemistry.chemical_compound, chemistry, Chemical engineering, visual_art, visual_art.visual_art_medium, High activity, Hydroxide, 0210 nano-technology, General Environmental Science
Abstract

Nanomaterials derived from earth-abundant metal oxides have gained tremendous interest as catalysts; although, water stability remains a challenge. This study examines MgO(111) surfaces for 2-pentanone condensation and their evolution during D2O hydration. Catalyst screening confirmed the high activity of fresh MgO(111) for 2-pentanone condensation relative to conventionally prepared MgO(100). Computational modeling suggests that the (111) surface is readily hydroxylated, and that surface hydroxyls help stabilize the surface and reduce the barrier for 2-pentanone condensation. Vapor-phase D2O hydration after 3 min increased MgO(111) hydroxyls and retained surface area and activity; however, after 1 h, deuteroxide formation reduced the surface area and activity by >30 %. After 24 h, deuteroxide growth slowed down, and surface area and activity remained stable. This suggests MgO(111)-derived hydroxide may be the dominant surface responsible for 2-pentanone condensation following water exposure. Thermal regeneration of the 24-h sample restored 86 % of the surface area and 94 % of the activity.

Published
2021
Full Text
View/download PDF

22. Ru-Sn/AC for the Aqueous-Phase Reduction of Succinic Acid to 1,4-Butanediol under Continuous Process Conditions

Author

Nicholas S. Cleveland, Kathleen Moyer, Derek R. Vardon, Amy E. Settle, Vassili Vorotnikov, Kevin N. Wood, Gregg T. Beckham, Todd R. Eaton, Martin J. Menart, Kinga A. Unocic, K. Xerxes Steirer, and William E. Michener

Subjects
010405 organic chemistry, Chemistry, Batch reactor, Aqueous two-phase system, General Chemistry, 1,4-Butanediol, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Succinic acid, medicine, Organic chemistry, Leaching (metallurgy), Bimetallic strip, Activated carbon, medicine.drug, Nuclear chemistry
Abstract

Succinic acid is a biomass-derived platform chemical that can be catalytically converted in the aqueous phase to 1,4-butanediol (BDO), a prevalent building block used in the polymer and chemical industries. Despite significant interest, limited work has been reported regarding sustained catalyst performance and stability under continuous aqueous-phase process conditions. As such, this work examines Ru-Sn on activated carbon (AC) for the aqueous-phase conversion of succinic acid to BDO under batch and flow reactor conditions. Initially, powder Ru-Sn catalysts were screened to determine the most effective bimetallic ratio and provide a comparison to other monometallic (Pd, Pt, Ru) and bimetallic (Pt-Sn, Pd-Re) catalysts. Batch reactor tests determined that a ∼1:1 metal weight ratio of Ru to Sn was effective for producing BDO in high yields, with complete conversion resulting in 82% molar yield. Characterization of the fresh Ru-Sn catalyst suggests that the sequential loading method results in Ru sites that ...

Published
2017
Full Text
View/download PDF

23. Performance-advantaged ether diesel bioblendstock production by a priori design

Author

P. Thathiana Benavides, Earl Christensen, Stephen M. Tifft, Seonah Kim, Derek R. Vardon, Xiangchen Huo, Teresa L. Alleman, Charles S. McEnally, Robert L. McCormick, Nabila A. Huq, Raynella M. Connatser, Jim Stunkel, Mary J. Biddy, Matthew R. Wiatrowski, Glenn R. Hafenstine, Lisa Fouts, Lisa D. Pfefferle, Peter C. St. John, Gina M. Fioroni, Michael D. Kass, and Patrick A. Cherry

Subjects
Multidisciplinary, business.industry, Lignocellulosic biomass, Pulp and paper industry, Catalysis, Renewable energy, law.invention, Ignition system, Diesel fuel, PNAS Plus, Biofuel, law, Environmental science, business, Cetane number, Oxygenate
Abstract

Lignocellulosic biomass offers a renewable carbon source which can be anaerobically digested to produce short-chain carboxylic acids. Here, we assess fuel properties of oxygenates accessible from catalytic upgrading of these acids a priori for their potential to serve as diesel bioblendstocks. Ethers derived from C(2) and C(4) carboxylic acids are identified as advantaged fuel candidates with significantly improved ignition quality (>56% cetane number increase) and reduced sooting (>86% yield sooting index reduction) when compared to commercial petrodiesel. The prescreening process informed conversion pathway selection toward a C(11) branched ether, 4-butoxyheptane, which showed promise for fuel performance and health- and safety-related attributes. A continuous, solvent-free production process was then developed using metal oxide acidic catalysts to provide improved thermal stability, water tolerance, and yields. Liter-scale production of 4-butoxyheptane enabled fuel property testing to confirm predicted fuel properties, while incorporation into petrodiesel at 20 vol % demonstrated 10% improvement in ignition quality and 20% reduction in intrinsic sooting tendency. Storage stability of the pure bioblendstock and 20 vol % blend was confirmed with a common fuel antioxidant, as was compatibility with elastomeric components within existing engine and fueling infrastructure. Technoeconomic analysis of the conversion process identified major cost drivers to guide further research and development. Life-cycle analysis determined the potential to reduce greenhouse gas emissions by 50 to 271% relative to petrodiesel, depending on treatment of coproducts.

Published
2019

24. Screening of Potential Biomass-Derived Streams as Fuel Blendstocks for Mixing Controlled Compression Ignition Combustion

Author

Earl Christensen, Derek R. Vardon, Nabila A. Huq, Xiangchen Huo, Russell Whitesides, Jon Luecke, Teresa L. Alleman, Evgueni Polikarpov, Lisa Fouts, Robert L. McCormick, Michael D. Kass, Gina M. Fioroni, and Goutham Kukkadapu

Subjects
Ignition system, Waste management, law, Environmental science, Biomass, STREAMS, Compression (physics), Combustion, Mixing (physics), law.invention
Published
2019
Full Text
View/download PDF

25. Metabolic engineering of Pseudomonas putida for increased polyhydroxyalkanoate production from lignin

Author

Darren J. Peterson, Rui Katahira, Jay D. Huenemann, Thomas Rydzak, William E. Michener, Holly Rohrer, Nicholas S. Cleveland, Joshua R. Elmore, Adam M. Guss, Derek R. Vardon, Jason T. Bouvier, Brenna A. Black, Anna Furches, Davinia Salvachúa, Raquel Auwae, Gregg T. Beckham, and Annette De Capite

Subjects
lcsh:Biotechnology, Bioengineering, engineering.material, Applied Microbiology and Biotechnology, Biochemistry, Lignin, Polyhydroxyalkanoates, Metabolic engineering, 03 medical and health sciences, chemistry.chemical_compound, Biosynthesis, lcsh:TP248.13-248.65, 030304 developmental biology, 0303 health sciences, Strain (chemistry), biology, 030306 microbiology, Chemistry, Pseudomonas putida, Brief Report, biology.organism_classification, Metabolic Engineering, Yield (chemistry), engineering, Brief Reports, Biopolymer, Corrigendum, Biotechnology
Abstract

Summary Microbial conversion offers a promising strategy for overcoming the intrinsic heterogeneity of the plant biopolymer, lignin. Soil microbes that natively harbour aromatic‐catabolic pathways are natural choices for chassis strains, and Pseudomonas putida KT2440 has emerged as a viable whole‐cell biocatalyst for funnelling lignin‐derived compounds to value‐added products, including its native carbon storage product, medium‐chain‐length polyhydroxyalkanoates (mcl‐PHA). In this work, a series of metabolic engineering targets to improve mcl‐PHA production are combined in the P. putida chromosome and evaluated in strains growing in a model aromatic compound, p‐coumaric acid, and in lignin streams. Specifically, the PHA depolymerase gene phaZ was knocked out, and the genes involved in β‐oxidation (fadBA1 and fadBA2) were deleted. Additionally, to increase carbon flux into mcl‐PHA biosynthesis, phaG, alkK, phaC1 and phaC2 were overexpressed. The best performing strain – which contains all the genetic modifications detailed above – demonstrated a 53% and 200% increase in mcl‐PHA titre (g l−1) and a 20% and 100% increase in yield (g mcl‐PHA per g cell dry weight) from p‐coumaric acid and lignin, respectively, compared with the wild type strain. Overall, these results present a promising strain to be employed in further process development for enhancing mcl‐PHA production from aromatic compounds and lignin., In this work, a series of metabolic engineering targets to improve mcl‐PHA production were combined in the P. putida chromosome and evaluated in strains growing in a model aromatic compound, p‐coumaric acid, and in lignin streams. Specifically, the PHA depolymerase gene (phaZ) and genes involved in β‐oxidation (fadBA1 and fadBA2) were deleted, while phaG, alkK, phaC1, and phaC2 were overexpressed to increase carbon flux from fatty acid biosynthesis to mcl‐PHA production. This strain demonstrated an increase in mcl‐PHA titer (g l−1) and yield (g mcl‐PHA per g cell dry weight) from p‐coumaric acid and from lignin compared to the wild‐type strain, resulting in a promising strain to be employed in further process development for enhancing mcl‐PHA production from aromatic compounds and lignin.

Published
2019

26. Heterogeneous Diels–Alder catalysis for biomass-derived aromatic compounds

Author

Gregg T. Beckham, Amy E. Settle, Ryan M. Richards, Derek R. Vardon, Laura Berstis, Nicholas A. Rorrer, and Yuriy Román-Leshkov

Subjects
010405 organic chemistry, fungi, Aromatization, Biomass, Solid acid, 010402 general chemistry, Heterogeneous catalysis, 01 natural sciences, Pollution, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Monomer, chemistry, Diels alder, Environmental Chemistry, Organic chemistry, Dehydrogenation
Abstract

In this tutorial review, we provide an overview of heterogeneous Diels–Alder catalysis for the production of lignocellulosic biomass-derived aromatic compounds. Diels–Alder reactions afford an extremely selective and efficient route for carbon–carbon cycloadditions to produce intermediates that can readily undergo subsequent dehydration or dehydrogenation reactions for aromatization. As a result, catalysis of Diels–Alder reactions with biomass-derived dienes and dienophiles has seen a growth of interest in recent years; however, significant opportunities remain to (i) tailor heterogeneous catalyst materials for tandem Diels–Alder and aromatization reactions, and (ii) utilize biomass-derived dienes and dienophiles to access both conventional and novel aromatic monomers. As such, this review discusses the mechanistic aspects of Diels–Alder reactions from both an experimental and computational perspective, as well as the synergy of Bronsted–Lewis acid catalysts to facilitate tandem Diels–Alder and aromatization reactions. Heterogeneous catalyst design strategies for Diels–Alder reactions are reviewed for two exemplary solid acid catalysts, zeolites and polyoxometalates, and recent efforts for targeting direct replacement aromatic monomers from biomass are summarized. Lastly, we point out important research directions for progressing Diels–Alder catalysis to target novel, aromatic monomers with chemical functionality that enables new properties compared to monomers that are readily accessible from petroleum.

Published
2017
Full Text
View/download PDF

27. Biomass-derived monomers for performance-differentiated fiber reinforced polymer composites

Author

Gregg T. Beckham, John R. Dorgan, Derek R. Vardon, Erica Gjersing, and Nicholas A. Rorrer

Subjects
chemistry.chemical_classification, Fumaric acid, Materials science, 010405 organic chemistry, Maleic anhydride, 02 engineering and technology, Dynamic mechanical analysis, Polymer, 021001 nanoscience & nanotechnology, 01 natural sciences, Pollution, 0104 chemical sciences, Styrene, Polyester, chemistry.chemical_compound, Monomer, chemistry, Methacrylic acid, Polymer chemistry, Environmental Chemistry, Composite material, 0210 nano-technology
Abstract

Nearly all polymer resins used to manufacture critically important fiber reinforced polymer (FRP) composites are petroleum sourced. In particular, unsaturated polyesters (UPEs) are widely used as matrix materials and are often based on maleic anhydride, a four-carbon, unsaturated diacid. Typically, maleic anhydride is added as a reactant in a conventional step-growth polymerization to incorporate unsaturation throughout the backbone of the UPE, which is then dissolved in a reactive diluent (styrene is widely used) infused into a fiber mat and cross-linked. Despite widespread historical use, styrene has come under scrutiny due to environmental and health concerns; in addition, many conceivable UPEs are not soluble in styrene. In this study, we demonstrate that renewably-sourced monomers offer the ability to overcome these issues and improve overall composite performance. The properties of poly(butylene succinate)-based UPEs incorporating maleic anhydride are used as a baseline for comparison against UPEs derived from fumaric acid, cis,cis-muconate, and trans,trans-muconate, all of which can be obtained biologically. The resulting biobased UPEs are combined with styrene, methacrylic acid, or a mixture of methacrylic acid and cinnaminic acid, infused into woven fiberglass and cross-linked with the addition of a free-radical initiator and heat. This process produces a series of partially or fully bio-derived composites. Overall, the muconate-containing UPE systems exhibit a more favorable property suite than the maleic anhydride and fumaric acid counterparts. In all cases at the same olefinic monomer loading, the trans,trans-muconate polymers exhibit the highest shear modulus, storage modulus, and glass transition temperature indicating stronger and more thermally resistant materials. They also exhibit the lowest loss modulus indicating a greater adhesion to the glass fibers. The use of a mixture of methacrylic and cinnaminic acid as the reactive diluent results in a FRP composite with properties that can be matched to reinforced composites prepared with styrene. Significantly, at one-third the monomer loading (corresponding to two-thirds the number of double bonds), trans,trans-muconate produces approximately the same storage modulus and glass transition temperature as maleic anhydride, while exhibiting a superior loss modulus. Overall, this work demonstrates the novel synthesis of performance-differentiated FRP composites using renewably-sourced monomers.

Published
2017
Full Text
View/download PDF

28. Renewable Unsaturated Polyesters from Muconic Acid

Author

Derek R. Vardon, John R. Dorgan, Nicholas A. Rorrer, Gregg T. Beckham, Yuan Yang, and Chelsea R. Martinez

Subjects
chemistry.chemical_classification, Terephthalic acid, Muconic acid, Ethylene, Condensation polymer, Renewable Energy, Sustainability and the Environment, Alkene, General Chemical Engineering, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Polybutylene succinate, Polyester, chemistry.chemical_compound, Dicarboxylic acid, chemistry, Polymer chemistry, Environmental Chemistry, Organic chemistry, 0210 nano-technology
Abstract

cis,cis-Muconic acid is an unsaturated dicarboxylic acid that can be produced in high yields via biological conversion of sugars and lignin-derived aromatic compounds. Muconic acid is often targeted as an intermediate to direct replacement monomers such as adipic or terephthalic acid. However, the alkene groups in muconic acid provide incentive for its direct use in polymers, for example, in the synthesis of unsaturated polyester resins. Here, biologically derived muconic acid is incorporated into polyesters via condensation polymerization using the homologous series of poly(ethylene succinate), poly(propylene succinate), poly(butylene succinate), and poly(hexylene succinate). Additionally, dimethyl cis,cis-muconate is synthesized and subsequently incorporated into poly(butylene succinate). NMR measurements demonstrate that alkene bonds are present in the polymer backbones. In all cases, the glass transition temperatures are increased whereas the melting and degradation temperatures are decreased. In the ...

Published
2016
Full Text
View/download PDF

29. Correction: Thermochemical wastewater valorization via enhanced microbial toxicity tolerance

Author

Jason M. Whitham, Gregg T. Beckham, Derek R. Vardon, Adam M. Guss, Nicholas S. Cleveland, Richard J. Giannone, Lahiru N. Jayakody, Jessica L. Olstad, Robert C. Brown, William E. Michener, Steven D. Brown, Brenna A. Black, Christopher W. Johnson, Robert L. Hettich, and Dawn M. Klingeman

Subjects
Nuclear Energy and Engineering, Wastewater, Renewable Energy, Sustainability and the Environment, Chemistry, Toxicity, Environmental Chemistry, Pulp and paper industry, Pollution
Abstract

Correction for ‘Thermochemical wastewater valorization via enhanced microbial toxicity tolerance’ by Lahiru N. Jayakody et al., Energy Environ. Sci., 2018, 11, 1625–1638, DOI: 10.1039/C8EE00460A.

Published
2021
Full Text
View/download PDF

30. cis,cis-Muconic acid: separation and catalysis to bio-adipic acid for nylon-6,6 polymerization

Author

Nicholas S. Cleveland, Amy E. Settle, Martin J. Menart, Nicholas A. Rorrer, Peter N. Ciesielski, Christopher W. Johnson, Derek R. Vardon, K. Xerxes Steirer, John R. Dorgan, Davinia Salvachúa, and Gregg T. Beckham

Subjects
chemistry.chemical_classification, Muconic acid, Adipic acid, 010405 organic chemistry, 010402 general chemistry, 01 natural sciences, Pollution, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Dicarboxylic acid, Adsorption, Nylon 6, chemistry, Polymerization, medicine, Environmental Chemistry, Organic chemistry, Activated carbon, medicine.drug
Abstract

cis,cis-Muconic acid is a polyunsaturated dicarboxylic acid that can be produced renewably via the biological conversion of sugars and lignin-derived aromatic compounds. Subsequently, muconic acid can be catalytically converted to adipic acid – the most commercially significant dicarboxylic acid manufactured from petroleum. Nylon-6,6 is the major industrial application for adipic acid, consuming 85% of market demand; however, high purity adipic acid (99.8%) is required for polymer synthesis. As such, process technologies are needed to effectively separate and catalytically transform biologically derived muconic acid to adipic acid in high purity over stable catalytic materials. To that end, this study: (1) demonstrates bioreactor production of muconate at 34.5 g L−1 in an engineered strain of Pseudomonas putida KT2440, (2) examines the staged recovery of muconic acid from culture media, (3) screens platinum group metals (e.g., Pd, Pt, Rh, Ru) for activity and leaching stability on activated carbon (AC) and silica supports, (4) evaluates the time-on-stream performance of Rh/AC in a trickle bed reactor, and (5) demonstrates the polymerization of bio-adipic acid to nylon-6,6. Separation experiments confirmed AC effectively removed broth color compounds, but subsequent pH/temperature shift crystallization resulted in significant levels of Na, P, K, S and N in the crystallized product. Ethanol dissolution of muconic acid precipitated bulk salts, achieving a purity of 99.8%. Batch catalysis screening reactions determined that Rh and Pd were both highly active compared to Pt and Ru, but Pd leached significantly (1–9%) from both AC and silica supports. Testing of Rh/AC in a continuous trickle bed reactor for 100 h confirmed stable performance after 24 h, although organic adsorption resulted in reduced steady-state activity. Lastly, polymerization of bio-adipic acid with hexamethyldiamine produced nylon-6,6 with comparable properties to its petrochemical counterpart, thereby demonstrating a path towards bio-based nylon production via muconic acid.

Published
2016
Full Text
View/download PDF

31. Towards lignin consolidated bioprocessing: simultaneous lignin depolymerization and product generation by bacteria

Author

Davinia Salvachúa, Gregg T. Beckham, Claire T. Nimlos, Derek R. Vardon, and Eric M. Karp

Subjects
Depolymerization, Microorganism, fungi, technology, industry, and agriculture, food and beverages, Biomass, Lignocellulosic biomass, complex mixtures, Pollution, Metabolic engineering, chemistry.chemical_compound, chemistry, Environmental Chemistry, Lignin, Organic chemistry, Bioprocess, Energy source
Abstract

Lignin represents an untapped resource in lignocellulosic biomass, primarily due to its recalcitrance to depolymerization and its intrinsic heterogeneity. In Nature, microorganisms have evolved mechanisms to both depolymerize lignin using extracellular oxidative enzymes and to uptake the aromatic species generated during depolymerization for carbon and energy sources. The ability of microbes to conduct both of these processes simultaneously could enable a Consolidated Bioprocessing concept to be applied to lignin, similar to what is done today with polysaccharide conversion to ethanol via ethanologenic, cellulolytic microbes. To that end, here we examine the ability of 14 bacteria to secrete ligninolytic enzymes, depolymerize lignin, uptake aromatic and other compounds present in a biomass-derived, lignin-enriched stream, and, under nitrogen-limiting conditions, accumulate intracellular carbon storage compounds that can be used as fuel, chemical, or material precursors. In shake flask conditions using a substrate produced during alkaline pretreatment, we demonstrate that up to nearly 30% of the initial lignin can be depolymerized and catabolized by a subset of bacteria. In particular, Amycolatopsis sp., two Pseudomonas putida strains, Acinetobacter ADP1, and Rhodococcus jostii are able to depolymerize high molecular weight lignin species and catabolize a significant portion of the low molecular weight aromatics, thus representing good starting hosts for metabolic engineering. This study also provides a comprehensive set of experimental tools to simultaneously study lignin depolymerization and aromatic catabolism in bacteria, and provides a foundation towards the concept of Lignin Consolidated Bioprocessing, which may eventually be an important route for biological lignin valorization.

Published
2015
Full Text
View/download PDF

32. Prediction of microalgae hydrothermal liquefaction products from feedstock biochemical composition

Author

Brajendra K. Sharma, Timothy J. Strathmann, Derek R. Vardon, John R. Witter, Jeremy S. Guest, and Shijie Leow

Subjects
Hydrothermal liquefaction, Molecular composition, Chemistry, Biofuel, Biochemical composition, Environmental Chemistry, Nannochloropsis oculata, Product characteristics, Raw material, Pulp and paper industry, Pollution, Quantitative model
Abstract

Hydrothermal liquefaction (HTL) uses water under elevated temperatures and pressures (200–350 °C, 5–20 MPa) to convert biomass into liquid “biocrude” oil. Despite extensive reports on factors influencing microalgae cell composition during cultivation and separate reports on HTL products linked to cell composition, the field still lacks a quantitative model to predict HTL conversion product yield and qualities from feedstock biochemical composition; the tailoring of microalgae feedstock for downstream conversion is a unique and critical aspect of microalgae biofuels that must be leveraged upon for optimization of the whole process. This study developed predictive relationships for HTL biocrude yield and other conversion product characteristics based on HTL of Nannochloropsis oculata batches harvested with a wide range of compositions (23–59% dw lipids, 58–17% dw proteins, 12–22% dw carbohydrates) and a defatted batch (0% dw lipids, 75% dw proteins, 19% dw carbohydrates). HTL biocrude yield (33–68% dw) and carbon distribution (49–83%) increased in proportion to the fatty acid (FA) content. A component additivity model (predicting biocrude yield from lipid, protein, and carbohydrates) was more accurate predicting literature yields for diverse microalgae species than previous additivity models derived from model compounds. FA profiling of the biocrude product showed strong links to the initial feedstock FA profile of the lipid component, demonstrating that HTL acts as a water-based extraction process for FAs; the remainder non-FA structural components could be represented using the defatted batch. These findings were used to introduce a new FA-based model that predicts biocrude oil yields along with other critical parameters, and is capable of adjusting for the wide variations in HTL methodology and microalgae species through the defatted batch. The FA model was linked to an upstream cultivation model (Phototrophic Process Model), providing for the first time an integrated modeling framework to overcome a critical barrier to microalgae-derived HTL biofuels and enable predictive analysis of the overall microalgal-to-biofuel process.

Published
2015
Full Text
View/download PDF

33. Adipic acid production from lignin

Author

Timothy J. Strathmann, Michael T. Guarnieri, Derek R. Vardon, Mary Ann Franden, Michael J. Salm, Gregg T. Beckham, Jeffrey G. Linger, Eric M. Karp, and Christopher W. Johnson

Subjects
chemistry.chemical_classification, Muconic acid, Adipic acid, Water transport, Renewable Energy, Sustainability and the Environment, Pollution, Catalysis, chemistry.chemical_compound, Dicarboxylic acid, Nuclear Energy and Engineering, chemistry, Environmental Chemistry, Organic chemistry, Lignin, Hemicellulose, Cellulose
Abstract

Lignin is an alkyl-aromatic polymer present in plant cell walls for defense, structure, and water transport. Despite exhibiting a high-energy content, lignin is typically slated for combustion in modern biorefineries due to its inherent heterogeneity and recalcitrance, whereas cellulose and hemicellulose are converted to renewable fuels and chemicals. However, it is critical for the viability of third-generation biorefineries to valorize lignin alongside polysaccharides. To that end, we employ metabolic engineering, separations, and catalysis to convert lignin-derived species into cis,cis-muconic acid, for subsequent hydrogenation to adipic acid, the latter being the most widely produced dicarboxylic acid. First, Pseudomonas putida KT2440 was metabolically engineered to funnel lignin-derived aromatics to cis,cis-muconate, which is an atom-efficient biochemical transformation. This engineered strain was employed in fed-batch biological cultivation to demonstrate a cis,cis-muconate titer of 13.5 g L−1 in 78.5 h from a model lignin-derived compound. cis,cis-Muconic acid was recovered in high purity (>97%) and yield (74%) by activated carbon treatment and crystallization (5 °C, pH 2). Pd/C was identified as a highly active catalyst for cis,cis-muconic acid hydrogenation to adipic acid with high conversion (>97%) and selectivity (>97%). Under surface reaction controlling conditions (24 °C, 24 bar, ethanol solvent), purified cis,cis-muconic acid exhibits a turnover frequency of 23–30 s−1 over Pd/C, with an apparent activation energy of 70 kJ mol−1. Lastly, cis,cis-muconate was produced with engineered P. putida grown on a biomass-derived, lignin-enriched stream, demonstrating an integrated strategy towards lignin valorization to an important commodity chemical.

Published
2015
Full Text
View/download PDF

34. Renewable acrylonitrile production

Author

Ryan T. Gill, Eric C. D. Tan, Todd R. Eaton, Gregg T. Beckham, Watson Michael John, Robin M. Cywar, Violeta Sànchez i Nogué, Derek R. Vardon, Vassili Vorotnikov, Adam D. Bratis, O. Stanley Fruchey, Michelle Gilhespy, Mary J. Biddy, Zinovia Skoufa, Lorenz P. Manker, Rongming Liu, Eric M. Karp, William E. Michener, and David G. Brandner

Subjects
Multidisciplinary, Materials science, Thermal runaway, 010405 organic chemistry, 010402 general chemistry, 01 natural sciences, Endothermic process, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Ammonia, chemistry, Chemical engineering, Titanium dioxide, Ethyl acrylate, Acrylonitrile, Ammoxidation
Abstract

A sweet source to make acrylonitrile Much of the attention directed toward displacing petroleum feedstocks with biomass has focused on fuels. However, there are also numerous opportunities in commodity chemical production. One such candidate is acrylonitrile, a precursor to a wide variety of plastics and fibers that is currently derived from propylene. Karp et al. efficiently manufactured this compound from an ester (ethyl 3-hydroxypropanoate) that can be sourced renewably from sugars. The process relies on inexpensive titania as a catalyst and avoids the side production of cyanide that accompanies propylene oxidation. Science , this issue p. 1307

Published
2017

35. Lignin valorization through integrated biological funneling and chemical catalysis

Author

Michael T. Guarnieri, Glendon B. Hunsinger, Gina M. Chupka, Timothy J. Strathmann, Gregg T. Beckham, Mary Ann Franden, Jeffrey G. Linger, Eric M. Karp, Derek R. Vardon, Christopher W. Johnson, and Philip T. Pienkos

Subjects
Multidisciplinary, Water transport, Materials science, fungi, technology, industry, and agriculture, food and beverages, Biomass, macromolecular substances, Biological Sciences, Biorefinery, Lignin, complex mixtures, Bioplastic, Catalysis, Polyhydroxyalkanoates, chemistry.chemical_compound, Metabolic pathway, chemistry, Organic chemistry, Cellulose
Abstract

Lignin is an energy-dense, heterogeneous polymer comprised of phenylpropanoid monomers used by plants for structure, water transport, and defense, and it is the second most abundant biopolymer on Earth after cellulose. In production of fuels and chemicals from biomass, lignin is typically underused as a feedstock and burned for process heat because its inherent heterogeneity and recalcitrance make it difficult to selectively valorize. In nature, however, some organisms have evolved metabolic pathways that enable the utilization of lignin-derived aromatic molecules as carbon sources. Aromatic catabolism typically occurs via upper pathways that act as a "biological funnel" to convert heterogeneous substrates to central intermediates, such as protocatechuate or catechol. These intermediates undergo ring cleavage and are further converted via the β-ketoadipate pathway to central carbon metabolism. Here, we use a natural aromatic-catabolizing organism, Pseudomonas putida KT2440, to demonstrate that these aromatic metabolic pathways can be used to convert both aromatic model compounds and heterogeneous, lignin-enriched streams derived from pilot-scale biomass pretreatment into medium chain-length polyhydroxyalkanoates (mcl-PHAs). mcl-PHAs were then isolated from the cells and demonstrated to be similar in physicochemical properties to conventional carbohydrate-derived mcl-PHAs, which have applications as bioplastics. In a further demonstration of their utility, mcl-PHAs were catalytically converted to both chemical precursors and fuel-range hydrocarbons. Overall, this work demonstrates that the use of aromatic catabolic pathways enables an approach to valorize lignin by overcoming its inherent heterogeneity to produce fuels, chemicals, and materials.

Published
2014
Full Text
View/download PDF

36. Thermochemical conversion of raw and defatted algal biomass via hydrothermal liquefaction and slow pyrolysis

Author

Derek R. Vardon, Brajendra K. Sharma, Timothy J. Strathmann, Kishore Rajagopalan, and Grant V. Blazina

Subjects
Magnetic Resonance Spectroscopy, Environmental Engineering, Biomass, Bioengineering, Raw material, Shale oil, Bioenergy, Spectroscopy, Fourier Transform Infrared, Spirulina, Plant Oils, Computer Simulation, Waste Management and Disposal, Distillation, Volatilisation, Waste management, Renewable Energy, Sustainability and the Environment, Chemistry, Temperature, Water, General Medicine, Elements, Lipids, Molecular Weight, Hydrothermal liquefaction, Biofuel, Biofuels, Chromatography, Gel, Thermodynamics, Pyrolysis, Biotechnology, Scenedesmus, Nuclear chemistry
Abstract

Thermochemical conversion is a promising route for recovering energy from algal biomass. Two thermochemical processes, hydrothermal liquefaction (HTL: 300 °C and 10-12 MPa) and slow pyrolysis (heated to 450 °C at a rate of 50 °C/min), were used to produce bio-oils from Scenedesmus (raw and defatted) and Spirulina biomass that were compared against Illinois shale oil. Although both thermochemical conversion routes produced energy dense bio-oil (35-37 MJ/kg) that approached shale oil (41 MJ/kg), bio-oil yields (24-45%) and physico-chemical characteristics were highly influenced by conversion route and feedstock selection. Sharp differences were observed in the mean bio-oil molecular weight (pyrolysis 280-360 Da; HTL 700-1330 Da) and the percentage of low boiling compounds (bp

Published
2012
Full Text
View/download PDF

37. The potential of laser scanning cytometry for early warning of algal blooms in desalination plant feedwater

Author

Derek R. Vardon, Mark M. Clark, and David A. Ladner

Subjects
Fouling, Mechanical Engineering, General Chemical Engineering, Red tide, fungi, Analytical chemistry, Soil science, General Chemistry, Biology, Desalination, Algal bloom, Laser Scanning Cytometry, General Materials Science, Seawater, Turbidity, Bloom, Water Science and Technology
Abstract

When algal blooms (such as red tide) occur, early detection of increased algal growth in intake water offers desalination plant operators advanced warning of severe fouling and provides the necessary time for preventative measures. Monitoring basic water quality measurements such as turbidity, silt density index (SDI), dissolved oxygen, and bulk fluorescence can approximate algal activity; however, these measurements lack the resolution needed to accurately track growth throughout all phases of a bloom event. This study investigates the use of a laser scanning cytometer (LSC) that detects algal cells over a wide range of concentrations (50–150,000 cells/ml), and characterizes cell shape, size, and distribution parameters through fluorescence signal imaging. Water samples are filtered to collect algae on a 0.2-μm membrane surface. Sample volume is variable so cells can be concentrated. The membrane surface is scanned with a 635-nm diode laser and the signal is processed to generate a cell count and distribution image. LSC performance was comparable to fluorescence microscopy and flow cytometry over a range of concentrations that may be encountered during a bloom event. The applicability of LSC was demonstrated using laboratory-grown cultures and seawater samples taken during a bloom event off of the coast of Long Beach, CA.

Published
2011
Full Text
View/download PDF

38. Effects of shear on microfiltration and ultrafiltration fouling by marine bloom-forming algae

Author

David A. Ladner, Derek R. Vardon, and Mark M. Clark

Subjects
chemistry.chemical_classification, Chromatography, biology, Fouling, Microfiltration, fungi, Filtration and Separation, biology.organism_classification, Biochemistry, Algal bloom, Desalination, Membrane, chemistry, Algae, Environmental chemistry, General Materials Science, Organic matter, Seawater, Physical and Theoretical Chemistry
Abstract

Pretreatment of seawater for desalination can be accomplished with microfiltration (MF) or ultrafiltration (UF) membranes. One problem with MF and UF pretreatment is fouling by marine algae, which is most prevalent during algal blooms. Algal cells quickly block MF and UF pores and decrease permeability. This paper investigates an important consideration in algal fouling: shear. A strain of bloom-forming dinoflagellate algae, Heterocapsa pygmaea , was grown in the laboratory for experiments. Algae were sheared by pumping through a highly restrictive valve. Sheared and non-sheared algal samples were filtered with four MF and UF membranes to determine the effects of shear on flux. Feed and permeate samples were analyzed to determine how shear affected organic-matter rejection. Sheared samples caused more drastic flux decline than non-sheared samples and rejection of algogenic organic matter (AOM) was diminished after shear. To determine the size of the foulants most responsible for flux decline, sheared and non-sheared samples were size fractionated before filtration on 0.1-μm PVDF membranes. The highly fouling fraction was cell-derived material larger than 0.22 μm. The algal cells themselves played only a small role in flux decline. High-molecular-weight organic material was released during shear, but flux decline did not correlate with its release; thus, adsorption of dissolved algogenic organic matter was not a significant fouling mechanism in these short-term experiments.

Published
2010
Full Text
View/download PDF

39. Cover Feature: Iodine-Catalyzed Isomerization of Dimethyl Muconate (ChemSusChem 11/2018)

Author

Amy E. Settle, Ryan M. Richards, Gregg T. Beckham, Derek R. Vardon, Shuting Zhang, Nicholas A. Rorrer, Laura Berstis, Haiming Hu, and Michael F. Crowley

Subjects
Muconic acid, Reaction mechanism, General Chemical Engineering, chemistry.chemical_element, Iodine, Photochemistry, Catalysis, chemistry.chemical_compound, General Energy, chemistry, Feature (computer vision), Environmental Chemistry, General Materials Science, Density functional theory, Cover (algebra), Isomerization
Published
2018
Full Text
View/download PDF

40. Chapter 5. Catalysis's Role in Bioproducts Update

Author

Derek R. Vardon, Kim Magrini-Bair, and Gregg T. Beckham

Subjects
Materials science, business.industry, Homogeneous, Bioproducts, Nanotechnology, Biochemical engineering, Biomass fuels, business, Commercialization, Catalysis, Renewable energy, Market penetration
Abstract

The goal for catalyst development, both homogeneous and heterogeneous, using bio-based feedstocks is designing new and robust materials for the dehydration, decarboxylation, decarbonylation, hydrogenolysis, esterification, and ketonization reactions that are required for converting these renewable, generally oxygenated feedstocks to desirable and renewable products. This chapter summarizes the work done on developing bio-based products in the last decade using the seminal US Department of Energy report on the top twelve bio-based chemicals as a starting point to assess catalyst improvement, novel process options, commercialization potential, and market penetration when possible.

Published
2015
Full Text
View/download PDF

41. Chemical properties of biocrude oil from the hydrothermal liquefaction of Spirulina algae, swine manure, and digested anaerobic sludge

Author

Lance Schideman, Derek R. Vardon, Brajendra K. Sharma, Timothy J. Strathmann, Guo Yu, Zhichao Wang, John W. Scott, and Yuanhui Zhang

Subjects
Environmental Engineering, Magnetic Resonance Spectroscopy, Swine, Sewage, Bioengineering, Raw material, Gas Chromatography-Mass Spectrometry, Spectroscopy, Fourier Transform Infrared, Spirulina, Animals, Anaerobiosis, Waste Management and Disposal, Spirulina (genus), biology, Waste management, Renewable Energy, Sustainability and the Environment, business.industry, Chemistry, General Medicine, Pulp and paper industry, biology.organism_classification, Manure, Hydrothermal liquefaction, Wastewater, Biofuel, Chromatography, Gel, Composition (visual arts), business
Abstract

This study explores the influence of wastewater feedstock composition on hydrothermal liquefaction (HTL) biocrude oil properties and physico-chemical characteristics. Spirulina algae, swine manure, and digested sludge were converted under HTL conditions (300°C, 10-12 MPa, and 30 min reaction time). Biocrude yields ranged from 9.4% (digested sludge) to 32.6% (Spirulina). Although similar higher heating values (32.0-34.7 MJ/kg) were estimated for all product oils, more detailed characterization revealed significant differences in biocrude chemistry. Feedstock composition influenced the individual compounds identified as well as the biocrude functional group chemistry. Molecular weights tracked with obdurate carbohydrate content and followed the order of Spirulina

Published
2011

42. Hydrothermal catalytic processing of saturated and unsaturated fatty acids to hydrocarbons with glycerol for in situ hydrogen production

Author

Timothy J. Strathmann, Brajendra K. Sharma, Dongwook Kim, Peter N. Ciesielski, Derek R. Vardon, Humberto Jaramillo, and Jong Kwon Choe

Subjects
chemistry.chemical_classification, Inorganic chemistry, Fatty acid, Pollution, chemistry.chemical_compound, Oleic acid, Hydrolysis, chemistry, Saturated fatty acid, Glycerol, Environmental Chemistry, Stearic acid, Deoxygenation, Unsaturated fatty acid, Nuclear chemistry
Abstract

Lipids are a promising feedstock to produce renewable hydrocarbon fuels and H2via catalytic hydrothermal processing. Upon exposure to hydrothermal media (e.g., 300 °C, 8–11 MPa), lipids rapidly hydrolyze to produce saturated and unsaturated free fatty acids in varying ratios, depending on the feedstock, as well as glycerol. This report demonstrates the potential of Pt–Re/C for the hydrothermal conversion of saturated and unsaturated fatty acids to hydrocarbons, using glycerol reforming for in situ H2 production to meet process demands. Experiments showed that deoxygenation of stearic acid, a model saturated fatty acid, was significantly enhanced with Pt–Re/C under a reducing atmosphere compared to Pt/C. The coupled hydrogenation and deoxygenation (HYD–DOX) of oleic aid, a model unsaturated fatty acid, was also moderately enhanced under an inert atmosphere using glycerol for in situ H2 production, with DOX as the rate-limiting step. Characterization of Pt–Re/C showed that Re had a significant effect on CO : H uptake ratio (2.2) compared to commercial Pt/C (1.3), with the metals dispersed as small crystallites (∼3–4 nm) throughout carbon support. Experiments revealed that the initial system H2 headspace loading

Published
2014
Full Text
View/download PDF

43. Complete Utilization of Spent Coffee Grounds To Produce Biodiesel, Bio-Oil, and Biochar

Author

Roque L. Evangelista, Kishore Rajagopalan, Bryan R. Moser, Timothy J. Strathmann, Katie R. Witkin, Brajendra K. Sharma, Wei Zheng, and Derek R. Vardon

Subjects
Biodiesel, Moisture, Renewable Energy, Sustainability and the Environment, Chemistry, business.industry, General Chemical Engineering, General Chemistry, Raw material, Pulp and paper industry, Defatting, Biotechnology, Boiling point, Biochar, Environmental Chemistry, business, Pyrolysis, Oxygenate
Abstract

This study presents the complete utilization of spent coffee grounds to produce biodiesel, bio-oil, and biochar. Lipids extracted from spent grounds were converted to biodiesel. The neat biodiesel and blended (B5 and B20) fuel properties were evaluated against ASTM and EN standards. Although neat biodiesel displayed high viscosity, moisture, sulfur, and poor oxidative stability, B5 and B20 met ASTM blend specifications. Slow pyrolysis of defatted coffee grounds was performed to generate bio-oil and biochar as valuable co-products. The effect of feedstock defatting was assessed through bio-oil analyses including elemental and functional group composition, compound identification, and molecular weight and boiling point distributions. Feedstock defatting reduced pyrolysis bio-oil yields, energy density, and aliphatic functionality, while increasing the number of low-boiling oxygenates. The high bio-oil heteroatom content will likely require upgrading. Additionally, biochar derived from spent and defatted gro...

44. The Techno-Economic Basis for Coproduct Manufacturing To Enable Hydrocarbon Fuel Production from Lignocellulosic Biomass

Author

Ryan Davis, Derek R. Vardon, Jeffrey G. Linger, Nancy Dowe, Gregg T. Beckham, Michael T. Guarnieri, Eric M. Karp, David Humbird, Mary J. Biddy, Ling Tao, and Davinia Salvachúa

Subjects
010405 organic chemistry, Renewable Energy, Sustainability and the Environment, business.industry, General Chemical Engineering, Vegetable oil refining, Lignocellulosic biomass, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Biorefinery, 01 natural sciences, 0104 chemical sciences, Biotechnology, Technical feasibility, Cost driver, Biofuel, Environmental Chemistry, Environmental science, Production (economics), 0210 nano-technology, Process engineering, business, Productivity
Abstract

Biorefinery process development relies on techno-economic analysis (TEA) to identify primary cost drivers, prioritize research directions, and mitigate technical risk for scale-up through development of detailed process designs. Here, we conduct TEA of a model 2000 dry metric ton-per-day lignocellulosic biorefinery that employs a two-step pretreatment and enzymatic hydrolysis to produce biomass-derived sugars, followed by biological lipid production, lipid recovery, and catalytic hydrotreating to produce renewable diesel blendstock (RDB). On the basis of projected near-term technical feasibility of these steps, we predict that RDB could be produced at a minimum fuel selling price (MFSP) of USD $9.55/gasoline-gallon-equivalent (GGE), predicated on the need for improvements in the lipid productivity and yield beyond current benchmark performance. This cost is significant given the limitations in scale and high costs for aerobic cultivation of oleaginous microbes and subsequent lipid extraction/recovery. In ...

45. Opportunities and challenges in biological lignin valorization

Author

Christopher W. Johnson, Davinia Salvachúa, Derek R. Vardon, Eric M. Karp, and Gregg T. Beckham

Subjects
0301 basic medicine, Biomedical Engineering, Microbial metabolism, Biomass, Lignocellulosic biomass, Bioengineering, complex mixtures, Lignin, Substrate Specificity, Metabolic engineering, 03 medical and health sciences, chemistry.chemical_compound, Bacteria, Chemistry, business.industry, fungi, technology, industry, and agriculture, food and beverages, Biorefinery, Biotechnology, 030104 developmental biology, Metabolic Engineering, Biofuel, Substrate specificity, Biochemical engineering, business
Abstract

Lignin is a primary component of lignocellulosic biomass that is an underutilized feedstock in the growing biofuels industry. Despite the fact that lignin depolymerization has long been studied, the intrinsic heterogeneity of lignin typically leads to heterogeneous streams of aromatic compounds, which in turn present significant technical challenges when attempting to produce lignin-derived chemicals where purity is often a concern. In Nature, microorganisms often encounter this same problem during biomass turnover wherein powerful oxidative enzymes produce heterogeneous slates of aromatics compounds. Some microbes have evolved metabolic pathways to convert these aromatic species via ‘upper pathways’ into central intermediates, which can then be funneled through ‘lower pathways’ into central carbon metabolism in a process we dubbed ‘biological funneling’. This funneling approach offers a direct, biological solution to overcome heterogeneity problems in lignin valorization for the modern biorefinery. Coupled to targeted separations and downstream chemical catalysis, this concept offers the ability to produce a wide range of molecules from lignin. This perspective describes research opportunities and challenges ahead for this new field of research, which holds significant promise towards a biorefinery concept wherein polysaccharides and lignin are treated as equally valuable feedstocks. In particular, we discuss tailoring the lignin substrate for microbial utilization, host selection for biological funneling, ligninolytic enzyme–microbe synergy, metabolic engineering, expanding substrate specificity for biological funneling, and process integration, each of which presents key challenges. Ultimately, for biological solutions to lignin valorization to be viable, multiple questions in each of these areas will need to be addressed, making biological lignin valorization a multidisciplinary, co-design problem.

46. Valorization of Waste Lipids through Hydrothermal Catalytic Conversion to Liquid Hydrocarbon Fuels with in Situ Hydrogen Production

Author

Dheeptha Murali, Derek R. Vardon, Timothy J. Strathmann, Brajendra K. Sharma, and Dongwook Kim

Subjects
chemistry.chemical_classification, Aqueous solution, 010405 organic chemistry, Renewable Energy, Sustainability and the Environment, General Chemical Engineering, General Chemistry, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Hydrolysis, Vegetable oil, Hydrocarbon, chemistry, Environmental Chemistry, Organic chemistry, Stearic acid, Methanol, Hydrogen production
Abstract

We demonstrate hydrothermal (300 °C, 10 MPa) catalytic conversion of real waste lipids (e.g., waste vegetable oil, sewer trap grease) to liquid hydrocarbon fuels without net need for external chemical inputs (e.g., H2 gas, methanol). A supported bimetallic catalyst (Pt–Re/C; 5 wt % of each metal) previously shown to catalyze both aqueous phase reforming of glycerol (a triacylglyceride lipid hydrolysis coproduct) to H2 gas and conversion of oleic and stearic acid, model unsaturated and saturated fatty acids, to linear alkanes was applied to process real waste lipid feedstocks in water. For reactions conducted with an initially inert headspace gas (N2), waste vegetable oil (WVO) was fully converted into linear hydrocarbons (C15–C17) and other hydrolyzed byproducts within 4.5 h, and H2 gas production was observed. Addition of H2 to the initial reactor headspace accelerated conversion, but net H2 production was still observed, in agreement with results obtained for aqueous mixtures containing model fatty acid...

Catalog

Books, media, physical & digital resources
See catalog results