Common processes drive the thermochemical pretreatment of lignocellulosic biomass

Paul Langan(University of Toledo), Loukas Petridis(University of Tennessee at Knoxville), Hugh O’Neill(Oak Ridge National Laboratory), Sai Venkatesh Pingali(Oak Ridge National Laboratory), Marcus Foston(Georgia Institute of Technology), Yoshiharu Nishiyama(Centre National de la Recherche Scientifique), Roland Schulz(University of Tennessee at Knoxville), Benjamin Lindner(Oak Ridge National Laboratory), B. Leif Hanson(University of Toledo), Shane E. Harton(Oak Ridge National Laboratory), William T. Heller(Oak Ridge National Laboratory), Volker S. Urban(Oak Ridge National Laboratory), Barbara R. Evans(Oak Ridge National Laboratory), S. Gnanakaran(Los Alamos National Laboratory), Arthur J. Ragauskas(Georgia Institute of Technology), Jeremy C. Smith(Oak Ridge National Laboratory), Brian H. Davison(Oak Ridge National Laboratory)
Green Chemistry
October 29, 2013
10.1039/c3gc41962b
Cited by 242Open Access
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Abstract

Lignocellulosic biomass, a potentially important renewable organic source of energy and chemical feedstock, resists degradation to glucose in industrial hydrolysis processes and thus requires expensive thermochemical pretreatments. Understanding the mechanism of biomass breakdown during these pretreatments will lead to more efficient use of biomass. By combining multiple probes of structure, sensitive to different length scales, with molecular dynamics simulations, we reveal two fundamental processes responsible for the morphological changes in biomass during steam explosion pretreatment: cellulose dehydration and lignin-hemicellulose phase separation. We further show that the basic driving forces are the same in other leading thermochemical pretreatments, such as dilute acid pretreatment and ammonia fiber expansion.

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