Molecular simulations that model cellulose microfibrils at high temperature indicate regions that may be easier to break down, which could lead to more efficient processing of cellulose into biofuel
Cellulose, the major component of plant matter, has a complex hierarchical structure that extends fr...
Much of the current interest in cellulose pyrolysis stems from technologies that enable the conversi...
Publisher's PDFThe condition of heat transfer to lignocellulosic biomass particles during thermal pr...
Natural plants, such as cotton and linen, are rich in cellulose Iβ. The properties of cellulose Iβ u...
The kinetics and products of cellulose pyrolysis can be studied using large-scale molecular dynamics...
Funding Information: We are grateful for the support by the FinnCERES Materials Bioeconomy Ecosystem...
Groundbreaking research at the National Renewable Energy Laboratory (NREL) has used supercomputing s...
Cellulose is one of the most abundant compounds found in nature. However, the environmental conditio...
We have modeled the transformation of cellulose Iβ to a high temperature (550 K) structure, which is...
Mechanism investigation of cellulose pyrolysis is remarkably useful for efficient utilization of bio...
Studying the high-temperature treatments of biomass-derived materials is essential to understand the...
The structural changes of cellulose in non-solvent liquid media can provide insights into the high-v...
Dissolution of cellulose is an important but complicated step in biofuel production fromlignocellulo...
It has been previously shown that cellulose-lignin droplets’ strong interactions, resulting from lig...
We study the thermal decomposition of cellulose using molecular simulations based on the ReaxFF reac...
Cellulose, the major component of plant matter, has a complex hierarchical structure that extends fr...
Much of the current interest in cellulose pyrolysis stems from technologies that enable the conversi...
Publisher's PDFThe condition of heat transfer to lignocellulosic biomass particles during thermal pr...
Natural plants, such as cotton and linen, are rich in cellulose Iβ. The properties of cellulose Iβ u...
The kinetics and products of cellulose pyrolysis can be studied using large-scale molecular dynamics...
Funding Information: We are grateful for the support by the FinnCERES Materials Bioeconomy Ecosystem...
Groundbreaking research at the National Renewable Energy Laboratory (NREL) has used supercomputing s...
Cellulose is one of the most abundant compounds found in nature. However, the environmental conditio...
We have modeled the transformation of cellulose Iβ to a high temperature (550 K) structure, which is...
Mechanism investigation of cellulose pyrolysis is remarkably useful for efficient utilization of bio...
Studying the high-temperature treatments of biomass-derived materials is essential to understand the...
The structural changes of cellulose in non-solvent liquid media can provide insights into the high-v...
Dissolution of cellulose is an important but complicated step in biofuel production fromlignocellulo...
It has been previously shown that cellulose-lignin droplets’ strong interactions, resulting from lig...
We study the thermal decomposition of cellulose using molecular simulations based on the ReaxFF reac...
Cellulose, the major component of plant matter, has a complex hierarchical structure that extends fr...
Much of the current interest in cellulose pyrolysis stems from technologies that enable the conversi...
Publisher's PDFThe condition of heat transfer to lignocellulosic biomass particles during thermal pr...
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