TY - JOUR
T1 - Hydrous pyrolysis of glucose using a rapid pulsed reaction technique
AU - Baniamerian, Hamed
AU - Høj, Martin
AU - Beier, Matthias Josef
AU - Jensen, Anker Degn
PY - 2023
Y1 - 2023
N2 - Hydrous pyrolysis of glucose is a promising method to produce glycolaldehyde and other valuable oxygenates in high yield. In this process, an aqueous glucose solution is sprayed into a fluidized bed at pyrolysis conditions. In this work, a pulsed chromatographic method is proposed for rapid investigation of the effect of operating parameters on the product distribution, especially the glycolaldehyde yield. This new technique also provided insights into the reaction pathways of hydrous glucose cracking and allowed to determine the time-frame in which the reaction takes place. From this, the reaction rate parameters for the kinetics of the retro-aldol condensation reaction leading to glycolaldehyde from glucose, e.g. apparent Arrhenius activation energy (E-a) could be derived. Furthermore, different sugars and different operating parameters such as temperature, carrier gas residence time, pulse injection volume, and solvent type were tested to understand the mechanism behind glucose cracking.
AB - Hydrous pyrolysis of glucose is a promising method to produce glycolaldehyde and other valuable oxygenates in high yield. In this process, an aqueous glucose solution is sprayed into a fluidized bed at pyrolysis conditions. In this work, a pulsed chromatographic method is proposed for rapid investigation of the effect of operating parameters on the product distribution, especially the glycolaldehyde yield. This new technique also provided insights into the reaction pathways of hydrous glucose cracking and allowed to determine the time-frame in which the reaction takes place. From this, the reaction rate parameters for the kinetics of the retro-aldol condensation reaction leading to glycolaldehyde from glucose, e.g. apparent Arrhenius activation energy (E-a) could be derived. Furthermore, different sugars and different operating parameters such as temperature, carrier gas residence time, pulse injection volume, and solvent type were tested to understand the mechanism behind glucose cracking.
U2 - 10.1039/d3re00268c
DO - 10.1039/d3re00268c
M3 - Journal article
SN - 2058-9883
VL - 8
SP - 2729
EP - 2737
JO - Reaction Chemistry and Engineering
JF - Reaction Chemistry and Engineering
IS - 11
ER -