Modeling pyrolytic behavior of pre-oxidized lignin using four representative ß-ether-type lignin-like model polymers

A better understanding of the pyrolytic characteristics of pre-oxidized lignin in which CαH–OH was oxidized to Cα=O group was obtained through four selected β-ether-type lignin-like model polymers containing the H- and G-type subunits. These models were depolymerized in closed ampoule reactor system...

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Veröffentlicht in:	Fuel processing technology 2018-07, Vol.176, p.221
Hauptverfasser:	Jiang, Weikun, Chu, Jiangyong, Wu, Shubin, Lucia, Lucian A
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Sprache:	eng
Schlagworte:	Aromatic compounds Chemical bonds Chemical reactions Depolymerization Lignin Mathematical models Monomers Oxidation Polymerization Pyrolysis
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creator	Jiang, Weikun Chu, Jiangyong Wu, Shubin Lucia, Lucian A
description	A better understanding of the pyrolytic characteristics of pre-oxidized lignin in which CαH–OH was oxidized to Cα=O group was obtained through four selected β-ether-type lignin-like model polymers containing the H- and G-type subunits. These models were depolymerized in closed ampoule reactor system and interrogated using in-situ FTIR. The results show that their degradation products differ significantly in species and yield due to CαH–OH, Cα=O, and aryl–OCH3. The yield of phenolic monomers from oxidized G-type polymer rose to 27.87 wt%, almost twice that of initial G-type polymer. Nevertheless, as for H-type polymer, oxidation of the CαH–OH to Cα=O group lead to decreases in phenolic monomers yield by ~half. The in-situ FTIR indicates that oxidation of the CαH–OH to Cα=O accelerates cleavage of interunit linkages and simplifies depolymerization pathways resulting in better selectivity of phenolic monomers, especially at low pyrolysis temperatures (
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These models were depolymerized in closed ampoule reactor system and interrogated using in-situ FTIR. The results show that their degradation products differ significantly in species and yield due to CαH–OH, Cα=O, and aryl–OCH3. The yield of phenolic monomers from oxidized G-type polymer rose to 27.87 wt%, almost twice that of initial G-type polymer. Nevertheless, as for H-type polymer, oxidation of the CαH–OH to Cα=O group lead to decreases in phenolic monomers yield by ~half. The in-situ FTIR indicates that oxidation of the CαH–OH to Cα=O accelerates cleavage of interunit linkages and simplifies depolymerization pathways resulting in better selectivity of phenolic monomers, especially at low pyrolysis temperatures (<500 °C). Several important transformation pathways are proposed that clearly explain the pyrolytic behavior of pre-oxidized polymers.</description><identifier>ISSN: 0378-3820</identifier><identifier>EISSN: 1873-7188</identifier><language>eng</language><publisher>Amsterdam: Elsevier Science Ltd</publisher><subject>Aromatic compounds ; Chemical bonds ; Chemical reactions ; Depolymerization ; Lignin ; Mathematical models ; Monomers ; Oxidation ; Polymerization ; Pyrolysis</subject><ispartof>Fuel processing technology, 2018-07, Vol.176, p.221</ispartof><rights>Copyright Elsevier Science Ltd. 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subjects	Aromatic compounds Chemical bonds Chemical reactions Depolymerization Lignin Mathematical models Monomers Oxidation Polymerization Pyrolysis
title	Modeling pyrolytic behavior of pre-oxidized lignin using four representative ß-ether-type lignin-like model polymers
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