Green polymer chemistry is now a global pursuit and comprises diverse disciplines, such as organic synthesis, polymer chemistry, material science, microbiology, molecular biology, catalysis, enzymology, environmental science, analytical chemistry, and chemical engineering. This field is equally active in the United States as well as Europe and Asia. Researchers, students, and people new to this field value a forum to meet and share ideas; this can take the form of a symposium dedicated to this field, or a special book that features the latest work done by leading practitioners.
"Green Polymer Chemistry: Biobased Materials and Biocatalysis" is a symposium series put on by the American Chemical Society that has been very successful and serves to bring together a community of scientists with different backgrounds but with common research interests. In the August 2017 symposium in Washington, D.C., there were a total of 84 presentations and 16 posters (one of the largest symposia in the meeting). The symposium was structured into 10 sessions:
-Bio-Based Materials: Industrial Perspectives
-Developments in Biocatalysts
-Green Biocatalytic Transformations
-Chemical Catalytic Routes to Bio-Based Materials
-New Reaction Strategies and Materials
-Polysaccharide-Based Materials
-Plant Oils and Ferulate-Based Materials
-Bio-Based Thermosetting Resins
-Therapeutics and Opto-Electronics
-Further Applications of Bio-Based Materials
Many of the leading researchers in this field accepted the invitation to speak, and they reported exciting findings in various areas, including new bio-based source materials, green conversion methods, new or improved processing methodologies, and green polymer-related products.
For convenience, this book is organized into seven sections: novel bioengineered approaches; new enzymatic methodologies; new materials based on polysaccharides; bio-related polyesters, polyamides, and polyurethanes; bio-based phenolics and composites; bio-based monomers and resulting products; and bio-based solvents and additives.
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1 Green Polymer Chemistry: Pipelines Toward New Products and Processes |
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1 | (14) |
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Novel Bioengineering Approaches |
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2 Bioorthogonal Approaches To Prepare Specifically Modified Functional Proteins |
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15 | (10) |
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3 Engineering the Microbial Cell Membrane To Improve Bioproduction |
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25 | (16) |
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4 Microbial Secretion System of Lactate-Based Oligomers and Its Application |
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41 | (22) |
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New Enzymatic Methodologies |
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5 Structural and Mutational Analysis of Polyethylene Terephthalate-Hydrolyzing Enzyme, Cut190, Based on Three-Dimensional Docking Structure with Model Compounds of Polyethylene Terephthalate |
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63 | (14) |
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6 Conjugates Based on Enzyme-Metal-Organic Frameworks for Advanced Enzymatic Applications |
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77 | (18) |
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7 Protease-Catalyzed Polymerization of Tripeptide Esters Containing Unnatural Amino Acids: α,α-Disubstituted and N-Alkylated Amino Acids |
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95 | (14) |
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New Materials Based on Polysaccharides |
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8 Sustainable Development of Polysaccharide Polyelectrolyte Complexes as Eco-Friendly Barrier Materials for Packaging Applications |
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109 | (16) |
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9 Effects of Monomer Compositions and Molecular Weight on Physical Properties of Alginic Acid Esters |
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125 | (12) |
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10 Preparation of Hydrophobically Modified Cashew Gum Through Reaction with Alkyl Ketene Dimer |
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137 | (12) |
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Bio-Related Polyesters, Polyamides, and Polyurethanes |
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11 Salicylic Acid-Based Poly(anhydride-esters): Synthesis, Properties, and Applications |
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149 | (14) |
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12 L-Lysine-Modified Poly(ester-urethane) Based on Polycaprolactone for Controlled Release of Hydrocortisone |
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163 | (14) |
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13 Rational Synthesis of Biobased Hyperbranched Poly(ester)s for Sustained Delivery |
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177 | (24) |
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14 Aromatic Bioplastics with Heterocycles |
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201 | (20) |
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Bio-Based Phenolics and Composites |
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15 Ferulic Acid- and Sinapic Acid-Based Bisphenols: Promising Renewable and Safer Alternatives to Bisphenol A for the Production of Bio-Based Polymers and Resins |
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221 | (32) |
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16 Application of Bio-Based Epoxy Resin as the Matrix for Composites |
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253 | (12) |
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17 Strategic Assemblies of Modified Xylochemicals for New Bio-Based Polymers and Composites |
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265 | (16) |
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18 Enhancing the Sustainability of High-Performance Fiber Composites |
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281 | (18) |
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Bio-Based Monomers and Resulting Products |
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19 Divinylglycol, a Glycerol-Based Monomer: Valorization, Properties, and Applications |
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299 | (32) |
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20 Levulinic Acid as Sustainable Feedstock in Polymer Chemistry |
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331 | (8) |
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21 Levulinic Acid: A Valuable Platform Chemical for the Fermentative Synthesis of Poly(hydroxyalkanoate) Biopolymers |
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339 | (16) |
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22 Bioadvantaged Nylon from Renewable Muconic Acid: Synthesis, Characterization, and Properties |
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355 | (14) |
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23 Bio-Based Monomers as a New Route to Improved Performance in Thermosetting Resins: Examples from Cyanate Ester Studies |
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369 | (16) |
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Bio-Based Solvents and Additives |
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24 Investigation of PolarClean and Gamma-Valerolactone as Solvents for Polysulfone Membrane Fabrication |
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385 | (20) |
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25 Flame Retardants from Renewable Sources: Food Waste, Plant Oils, and Starch |
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405 | (22) |
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423 | (4) |
| Indexes |
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| Author Index |
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427 | (2) |
| Subject Index |
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429 | |
H. N. Cheng (Ph.D., University of Illinois) is currently a research chemist at Southern Regional Research Center of the U.S. Department of Agriculture in New Orleans, where he works on projects involving improved utilization of commodity agricultural materials, green chemistry, and polymer reactions. Prior to 2009 he worked for Hercules Incorporated, where he was involved at various times with new product development, team and project leadership, new business evaluation, pioneering research, and supervision of analytical research. Over the years, his research interests have included green polymer chemistry, agro-based materials, biocatalysis, pulp and paper chemistry, functional foods, polymer characterization, and NMR spectroscopy. He was elected an ACS Fellow (2009), a POLY Fellow (2010), and an AGFD Fellow (2018). He received the ACS Volunteer Service Award (2016), Tillmans-Skolnick Award for Outstanding Service from the ACS Delaware Section (2006), and Distinguished Service (2005) and
Special Service (2015) Awards from ACS Polymer Division. He has authored or co-authored over 250 papers, 26 patent publications, co-edited 20 books, and organized or co-organized 33 symposia at national ACS meetings since 2003.
Richard A. Gross (Ph.D., Polytechnic University) holds Constellation Chaired Professorship at Rensselaer Polytechnic Institute (RPI) and is also a member of RPI's Departments of Chemistry and Biology as well as Biomedical Engineering. Previously he was on the faculty of University of Massachusetts (Lowell) (1988?1998) and occupied the Herman F. Mark Chair Professorship at Polytechnic University (1998-2013). His research is focused on developing biocatalytic routes to bio-based materials, combining chemical methods with cell-free and whole-cell biocatalytic systems to produce a large number of new biobased materials. He has over 400 publications in peer-reviewed journals with approximately 26,000 citations, has edited 7 books, and has been granted or filed 26 patents.
He has received numerous awards, including Presidential Green Chemistry Award in the academic category (2003), induction into the American Institute for Medical and Biological Engineering (2007), Turner Alfrey Visiting Professor (2010), POLY Fellow (2015), Lifetime Achievement Award from the Bio-Environmental Polymer Society (2017), and the 2018 recipient of the Affordable Green Chemistry Award from the ACS. He founded SyntheZyme, LLC (where he serves as Chief Technology Officer) in 2009 to commercialize technologies developed in his laboratory.
Patrick B. Smith (Ph.D., Michigan State University) is an Adjunct Professor at both Michigan State University and Central Michigan University. He joined the Dow Chemical Company in 1974, rising to the rank of Fellow prior to his retirement in 2007. At Dow, he served with Cargill Dow Polymers, which launched the IngeoTM PLA line of products. After his retirement from Dow, he consulted with Archer Daniels Midland, acting as ADM's R&D leader for their
joint venture with Metabolix, which commercialized MirelTM PHA biopolymers. He also supported ADM's bio-based propylene glycol product launch. He received the Sigma Xi Midland Chapter Award in 1987 and the ACS Midland Section Award for Outstanding Achievement and Promotion of the Chemical Sciences in 1998. He was named an ACS Fellow in 2013 and received the ACS E. Ann Nalley Award in 2014. He is also the recipient of Dow Analytical Science's V.A. Stenger Award in 1984 and the Dow Michigan R&D Scientists' Award in 1994. He has co-authored nearly 500 Dow technical reports, 90 publications, and 3 patents.
