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Cellulose
Published in: Cellulose 6/2011

01-12-2011

An improved model for the kinetic description of the thermal degradation of cellulose

Authors: Pedro E. Sánchez-Jiménez, Luis A. Pérez-Maqueda, Antonio Perejón, José Pascual-Cosp, Mónica Benítez-Guerrero, José M. Criado

Published in: Cellulose | Issue 6/2011

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Abstract

In spite of the large amount of work performed by many investigators during last decade, the actual understanding of the kinetics of thermal degradation of cellulose is still largely unexplained. In this paper, recent findings suggesting a nucleation and growth of nuclei mechanism as the main step of cellulose degradation have been reassessed and a more appropriate model involving chain scission and volatilization of fragments has been proposed instead. The kinetics of cellulose pyrolysis have been revisited by making use of a novel kinetic method that, without any previous assumptions regarding the kinetic model, allows performing the kinetic analysis of a set of experimental curves recorded under different heating schedules. The kinetic parameters and kinetic model obtained allows for the reconstruction of the whole set of experimental TG curves.
previous article Fabrication of carbon nanofiber by pyrolysis of freeze-dried cellulose nanofiber
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Literature
Agrawal RK (1988a) Kinetics of reactions involved in pyrolysis of cellulose.1. The 3-reaction model. Can J Chem Eng 66(3):403–412CrossRef
Agrawal RK (1988b) Kinetics of reactions involved in pyrolysis of cellulose.2. The modified Kilzer-Broido Model. Can J Chem Eng 66(3):413–418CrossRef
Antal MJ, Varhegyi G, Jakab E (1998) Cellulose pyrolysis kinetics: revisited. Ind Eng Chem Res 37(4):1267–1275CrossRef
Arii T, Ichihara S, Nakagawa H, Fujii N (1998) A kinetic study of the thermal decomposition of polyesters by controlled-rate thermogravimetry. Thermochim Acta 319(1–2):139–149CrossRef
Barneto A, Carmona J, Alfonso JE, Alcaide L (2009) Use of autocatalytic kinetics to obtain composition of lignocellulosic materials. Bioresour Technol 100(17):3963–3973CrossRef
Bigger SW, Scheirs J, Camino G (1998) An investigation of the kinetics of cellulose degradation under non-isothermal conditions. Polym Degrad Stab 62(1):33–40CrossRef
Bradbury AGW, Sakai Y, Shafizadeh F (1979) Kinetic model for pyrolysis of cellulose. J Appl Polym Sci 23(11):3271–3280CrossRef
Calvini P (2005) The influence of levelling-off degree of polymerisation on the kinetics of cellulose degradation. Cellulose 12(4):445–447CrossRef
Calvini P (2008) Comments on the article “On the degradation evolution equations of cellulose” by Hongzhi Ding and Zhongdong Wang. Cellulose 15(2):225–228CrossRef
Calvini P, Gorassini A, Merlani AL (2008) On the kinetics of cellulose degradation: looking beyond the pseudo zero order rate equation. Cellulose 15(2):193–203CrossRef
Capart R, Khezami L, Burnham AK (2004) Assessment of various kinetic models for the pyrolysis of a microgranular cellulose. Thermochim Acta 417(1):79–89CrossRef
Criado JM, Morales J (1976) Defects of thermogravimetric analysis for Discerning Between 1st order reactions and those taking place through Avrami-Erofeevs mechanism. Thermochim Acta 16(3):382–387CrossRef
Criado JM, Morales J (1977) Thermal decomposition reactions of solids controlled by diffusion and phase-boundary processes—possible misinterpretation from thermogravimetric data. Thermochim Acta 19(3):305–317CrossRef
Criado JM, Perez-Maqueda LA, Gotor FJ, Malek J, Koga N (2003) A unified theory for the kinetic analysis of solid state reactions under any thermal pathway. J Therm Anal Calorim 72(3):901–906CrossRef
Criado JM, Sanchez-Jimenez PE, Perez-Maqueda LA (2008) Critical study of the isoconversional methods of kinetic analysis. J Therm Anal Calorim 92(1):199–203CrossRef
Ding HZ, Wang ZD (2008a) Author response to the comments by P. Calvini regarding the article “On the degradation evolution equations of cellulose” by H.-Z. Ding and Z. D. Wang. Cellulose 15(2):229–237CrossRef
Ding HZ, Wang ZD (2008b) On the degradation evolution equations of cellulose. Cellulose 15(2):205–224CrossRef
Dollimor D, Holt B (1973) Thermal degradation of cellulose in nitrogen. J Polym Sci Part B Polym Phys 11(9):1703–1711
Emsley AM (2008) Cellulosic ethanol re-ignites the fire of cellulose degradation. Cellulose 15(2):187–192CrossRef
Ganster J, Fink HP (2006) Novel cellulose fibre reinforced thermoplastic materials. Cellulose 13(3):271–280CrossRef
Kilzer FJ, Broido A (1965) Speculation on the nature of cellulose pyrolysis. Pyrodynamics 2:151–163
Koga N, Criado JM (1998) The influence of mass transfer phenomena on the kinetic analysis for the thermal decomposition of calcium carbonate by constant rate thermal analysis (CRTA) under vacuum. Int J Chem Kinet 30(10):737–744CrossRef
Lin YC, Cho J, Tompsett GA, Westmoreland PR, Huber GW (2009) Kinetics and mechanism of cellulose pyrolysis. J Phys Chem C 113(46):20097–20107CrossRef
Liu HY, Liu DG, Yao F, Wu QL (2010) Fabrication and properties of transparent polymethylmethacrylate/cellulose nanocrystals composites. Bioresour Technol 101(14):5685–5692CrossRef
Mamleev V, Bourbigot S, Le Bras M, Yvon J, Lefebvre J (2006) Model-free method for evaluation of activation energies in modulated thermogravimetry and analysis of cellulose decomposition. Chem Eng Sci 61(4):1276–1292CrossRef
Mamleev V, Bourbigot S, Yvon J (2007a) Kinetic analysis of the thermal decomposition of cellulose: the change of the rate limitation. J Anal Appl Pyrol 80(1):141–150CrossRef
Mamleev V, Bourbigot S, Yvon J (2007b) Kinetic analysis of the thermal decomposition of cellulose: the main step of mass loss. J Anal Appl Pyrol 80(1):151–165CrossRef
Mamleev V, Bourbigot S, Le Bras M, Yvon J (2009) The facts and hypotheses relating to the phenomenological model of cellulose pyrolysis Interdependence of the steps. J Anal Appl Pyrol 84(1):1–17CrossRef
Mohan D, Pittman CU, Steele PH (2006) Pyrolysis of wood/biomass for bio-oil: a critical review. Energy Fuels 20(3):848–889CrossRef
PerezMaqueda LA, Ortega A, Criado JM (1996) The use of master plots for discriminating the kinetic model of solid state reactions from a single constant-rate thermal analysis (CRTA) experiment. Thermochim Acta 277:165–173CrossRef
Perez-Maqueda LA, Criado JM, Subrt J, Real C (1999) Synthesis of acicular hematite catalysts with tailored porosity. Catal Lett 60(3):151–156CrossRef
Perez-Maqueda LA, Criado JM, Gotor FJ (2002a) Controlled rate thermal analysis commanded by mass spectrometry for studying the kinetics of thermal decomposition of very stable solids. Int J Chem Kinet 34(3):184–192CrossRef
Perez-Maqueda LA, Criado JM, Gotor FJ, Malek J (2002b) Advantages of combined kinetic analysis of experimental data obtained under any heating profile. J Phys Chem A 106(12):2862–2868CrossRef
Perez-Maqueda LA, Criado JM, Malek J (2003) Combined kinetic analysis for crystallization kinetics of non-crystalline solids. J Non-Cryst Solids 320(1–3):84–91CrossRef
Perez-Maqueda LA, Criado JM, Sanchez-Jimenez PE (2006) Combined kinetic analysis of solid-state reactions: a powerful tool for the simultaneous determination of kinetic parameters and the kinetic model without previous assumptions on the reaction mechanism. J Phys Chem A 110(45):12456–12462CrossRef
Reynolds JG, Burnham AK (1997) Pyrolysis decomposition kinetics of cellulose-based materials by constant heating rate micropyrolysis. Energy Fuels 11(1):88–97CrossRef
Rouquerol J (2003) A general introduction to SCTA and to rate-controlled SCTA. J Therm Anal Calorim 72(3):1081–1086CrossRef
Saddawi A, Jones JM, Williams A, Wojtowicz MA (2010) Kinetics of the Thermal Decomposition of Biomass. Energy Fuels 24:1274–1282CrossRef
Sanchez-Jimenez PE, Perez-Maqueda LA, Perejon A, Criado JM (2009) Combined kinetic analysis of thermal degradation of polymeric materials under any thermal pathway. Polym Degrad Stab 94(11):2079–2085CrossRef
Sanchez-Jimenez PE, Perejon A, Criado JM, Dianez MJ, Perez-Maqueda LA (2010a) Kinetic model for thermal dehydrochlorination of poly(vinyl chloride). Polymer 51(17):3998–4007CrossRef
Sanchez-Jimenez PE, Perez-Maqueda LA, Crespo-Amoros JE, Lopez J, Perejon A, Criado JM (2010b) Quantitative characterization of multicomponent polymers by sample-controlled thermal analysis. Anal Chem 82(21):8875–8880CrossRef
Sanchez-Jimenez PE, Perez-Maqueda LA, Perejon A, Criado JM (2010c) A new model for the kinetic analysis of thermal degradation of polymers driven by random scission. Polym Degrad Stab 95(5):733–739CrossRef
Sánchez-Jiménez PE, Pérez-Maqueda LA, Perejón A, Criado JM (2011) Constant rate thermal analysis fot thermal stability studies of polymers. Polym Degrad Stab 96(5):974–981
Sestak J, Berggren G (1971) Study of the kinetics of the mechanism of solid-state reactions at increased temperature. Thermochim Acta 3:1–12CrossRef
Shen DK, Gu S (2009) The mechanism for thermal decomposition of cellulose and its main products. Bioresour Technol 100(24):6496–6504CrossRef
Simha R, Wall LA (1952) Kinetics of chain depolymerization. J Phys Chem 56(6):707–715CrossRef
Varhegyi G, Jakab E, Antal MJ (1994) Is the Broido-Shafizadeh model for cellulose true? Energy Fuels 8(6):1345–1352CrossRef
Volker S, Rieckmann T (2002) Thermokinetic investigation of cellulose pyrolysis—impact of initial and final mass on kinetic results. J Anal Appl Pyrol 62(2):165–177CrossRef
Metadata
Title
An improved model for the kinetic description of the thermal degradation of cellulose
Authors
Pedro E. Sánchez-Jiménez
Luis A. Pérez-Maqueda
Antonio Perejón
José Pascual-Cosp
Mónica Benítez-Guerrero
José M. Criado
Publication date
01-12-2011
Publisher
Springer Netherlands
Published in
Cellulose / Issue 6/2011
Print ISSN: 0969-0239
Electronic ISSN: 1572-882X
DOI
https://doi.org/10.1007/s10570-011-9602-3

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