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1. Elucidation of Structure and Physical Properties of Pyrolytic Sugar Oligomers Derived from Cellulose Depolymerization/Dehydration Reactions: A Density Functional Theory Study

   https://doi.org/10.1021/acs.energyfuels.3c00641  

   Denson, Melba Domes; Terrell, Evan; Kostetskyy, Pavlo; Olarte, Mariefel; Broadbelt, Linda; Garcia-Perez, Manuel (June 2023, Energy & Fuels)

   Hongwei Wu (Ed.)

   Fast pyrolysis of lignocellulosic materials is a promising research area to produce renewable fuels and chemicals. Dehydration is known to be among the most important reaction families during cellulose pyrolysis; water is the most important product. Together with water, dehydration reactions also form a range of poorly known oligomer species of varying molecular sizes, often collected as part of the bio-oil water-soluble (WS) fraction. In this work, we used electronic structure calculations to evaluate the relative thermodynamic stabilities of several oligomer species from cellulose depolymerization intermediates undergoing three consecutive dehydration events. A library of the thermodynamically favored candidate molecular structures was compiled. Results revealed that most of the water molecules are eliminated from the non-reducing end, forming thermodynamically more stable conjugated compounds. This is consistent with results reported in literature where dehydration reactions occur preferably at the non-reducing ends of oligomers. The theoretical Fourier-Transform Infrared Spectroscopy and NMR spectra of these proposed sugar oligomers conform qualitatively to the experimental result of pyrolytic sugars. Understanding their chemical structure could help to develop rational strategies to mitigate coke formation as sugars are often blamed to cause coke formation during bio-oil refining. The estimated physical–chemical properties (boiling point, melting point, Gibbs free energy of formation, enthalpy of formation, and solubility parameters among others) are also fundamental to conducting first-principles engineering calculations to design and analyze new pyrolysis reactors and bio-oil up-grading units. 

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2. Selective Lignin Depolymerization via Transfer Hydrogenolysis Using Hydrotalcite Supported Palladium – Model Compounds to Application

   Darren Dolan, Rebekah Brucato (December 2022, ChemRxiv)

   The cleavage of lignin ether bonds via transfer hydrogenolysis remains a promising route for the valorization of lignin. To make this process efficient, a method would need to be developed that utilizes mild conditions and a renewable hydrogen donor solvent, in addition to avoiding high pressure of hydrogen. Herein, we demonstrate the efficient catalytic transfer hydrogenolysis of lignin model compounds possessing aromatic ether bonds, including α-O-4, β-O-4 and 4-O-5 linkages, using Pd-doped hydrotalcites as heterogeneous catalysts and ethanol as the hydrogen donor. Catalysts that can carry out transfer hydrogenolysis and decarbonylation in tandem are yet to be reported. Quantitative conversions and yields were realized for all model compounds studied, demonstrating the utility of the metal-doped hydrotalcites for this catalytic application. The system was applied to whole pine biomass to achieve delignification (86%) and a phenolic monomer yield of 39%. 

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3. Catalytic and Inhibitory Effects Induced by Noncovalent Interactions between Cellulose and Lignin during Fast Pyrolysis

   https://doi.org/10.1021/acssuschemeng.4c00481  

   Sakirler, Fuat; Tekbas, M Doga; Wong, Hsi-Wu (June 2024, ACS Sustainable Chemistry & Engineering)

   Biomass fast pyrolysis has emerged as a highly promising technology for producing renewable fuels and chemicals. However, the inherent multi-scale and multiphase nature of the process and the heterogeneous nature of biomass feedstocks typically lead to low selectivity toward each bio-oil molecule, posing significant commercialization challenges. Molecular-level understanding of the biomass pyrolysis reaction kinetics considering the interactions between the main constituents (i.e., cellulose, hemicellulose, and lignin) is essential to advance the macroscopic design, scale-up, and optimization of the process. In this work, microreactor experiments were conducted to determine the effects of lignin structures on the yields of cellulose-derived products during pyrolysis. We show that levoglucosan formation is inhibited by the β-O-4 lignin linkages or catalyzed by the 5-5 linkages, glycolaldehyde formation is catalyzed by the β-O-4 linkages or inhibited by the 5-5 linkages, and 5-hydroxymethylfurfural formation is inhibited by either linkage. Density functional theory calculations reveal that these catalytic and inhibitory effects on cellulose fast pyrolysis are induced by noncovalent interactions between cellulose and lignin. The molecular-level picture of cellulose–lignin interactions uncovered in this work paves the way for further use of genetic engineering to grow new genotypes of biomass for selective production of value-added chemicals and machine learning approaches to obtain correlations between biomass structures and product yields for biomass fast pyrolysis. 

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4. Producing high yield of levoglucosan by pyrolyzing nonthermal plasma-pretreated cellulose

   https://doi.org/10.1039/d0gc00255k  

   A, Lusi; Hu, Haiyang; Bai, Xianglan (March 2020, Green Chemistry)

   Atmospheric pressure nonthermal plasma treatment can be a novel, green and low energy method to convert biomass to biobased chemicals. The unique physiochemistry of plasma discharge enables reactions within biomass that otherwise could not possibly occur under traditional conditions. In this study, we present a simple method of producing a high yield of levoglucosan from cellulose without using any catalysts, chemicals, solvents or vacuum, but by using plasma treatment to control the depolymerization mechanism of cellulose. Cellulose was first pretreated in a dielectric barrier discharge reactor operating in ambient air or argon for 10–60 s, followed by pyrolysis at 350–450 °C to produce up to 78.6% of levoglucosan. Without the plasma pretreatment, the maximum yield of levoglucosan from cellulose pyrolysis was 58.2%. The results of this study showed that the plasma pretreatment led to homolytic cleavage of glycosidic bonds. The resulting free radicals were then trapped within the cellulose structure when the plasma discharge stopped, allowing subsequent pyrolysis of the plasma-pretreated cellulose to proceed through a radical-based mechanism. The present results also revealed that although the radical-based mechanism is highly selective to levoglucosan formation, this pathway is usually discouraged when the untreated cellulose is pyrolyzed due to the high energy barrier for homolytic cleavage. Initiating homolytic cleavage during the plasma pretreatment also helped the pretreated cellulose to produce higher yields of levoglucosan using lower pyrolysis temperatures. At 375 °C, the levoglucosan yield was only 53.2% for the untreated cellulose, whereas the yield reached 77.6% for the argon-plasma pretreated cellulose. 

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5. 5–5 Lignin Linkage Cleavage over Ru: A Density Functional Theory Study

   https://doi.org/10.1021/acssuschemeng.1c04838  

   Li, Qiang; Vlachos, Dionisios G (December 2021, ACS Sustainable Chemistry & Engineering)

   Lignin is the most abundant natural, aromatic-containing biopolymer. Among all the C–C and C–O bonds being cleaved in catalytic fractionation, the 5–5 linkage is the strongest, and its scission requires harsh conditions. Theoretical investigations of the mechanism and kinetics could provide insights into developing better catalysts but are essentially lacking. We perform extensive density functional theory calculations on 2-methoxy-1,1′-biphenyl, a model compound, with various substitutions at all ring locations on Ru(0001). We analyze the competition between the 5–5 bond cleavage and the defunctionalization of the side functional groups at multiple degrees of depolymerization. The role of ring functional groups in the adsorption of lignin oligomers and the 5–5 bond scission and, conversely, the effect of the aromatic group on the −OCH3 decomposition are also discussed. We show that increasing the number of methoxy groups decreases the C–C barrier, and thus, we expect the following depolymerization ranking: grass > softwood > hardwood. While Ru exposes modest 5–5 bond scission reaction barriers from some intermediates, rapid side group chemistry prevents the formation of these intermediates; instead, scission happens most probably from defunctionalized compounds whose C–C scission barriers are high. Our results also expose the existence of multiple Brønsted–Evans–Polanyi relations in the catalytic transformation of biphenyl-based molecules that open up the possibility of modeling depolymerization of large lignin chains. 

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