Lignocellulosic biomass is a valuable alternative raw material to partially substitute oil as both energy
and chemical source. For example, polysaccharide constituents of lignocellulosic materials,
hemicellulose and cellulose, can be hydrolytically depolymerized using acid catalysts or enzymes,
while residual lignin can be used as a source of aromatic building blocks.
The kinetic severity of the hydrolysis process can be adjusted to maximize alternatively the yields in
fermentable sugars (bioethanol-way) or in chemicals such as furfural, hydroxymethylfurfural, levulinic
acid. It is well known that, before performing the main hydrolysis step, a pretreatment stage of the matrix is necessary to cleave the bonds between
hemicellulose, cellulose and lignin and to start breaking some of the polysaccharide chains. Liquid hot water (LHW) can be used for the pretreatment of biomass, without adding any acid to the system, thus avoiding the need of any subsequent neutralization step.
In order to move toward industrial scale plant for production of energy and bulk chemicals from
biomasses, continuous systems are desirable. An intermediate step toward the design of a continuous
layout is constituted by semi-continuous processes.
In this study, we have performed the LHW pretreatment of Arundo Donax (giant reed) in two different
systems: a microwave (MW)-assisted batch reactor, where high heating rate can be achieved leading
rapidly the system at the operative conditions of the pretreatment, and a fast heating flow-through
layout in which the flow rate of the process water stream can be tuned. The achieved
results highlight that in the microwave (MW)-assisted batch reactor good hemicelluloses solubilization,
little sugar degradation and insignificant lignin and cellulose fractionation can be obtained by
optimizing reaction temperature and time and that in the flow-through system high biomass conversion
as well as very limited formation of degradation products can be obtained by adjusting the flow rate of
the treatment water