Coupling hydrothermal liquefaction and aqueous phase reforming for integrated production of biocrude and renewable H₂

Abstract: Lignin-rich stream from lignocellulosic ethanol production was converted into biocrude by continuous hydrothermal liquefaction (HTL) while hydrogen was produced by aqueous phase reforming (APR) of the HTL aqueous by-product. The effects of Na 2 CO 3 and NaOH were investigated both in terms of processability of the feedstock as well as yield and composition of the obtained products. A maximum biocrude yield of 27 wt% was reached in the NaOH-catalyzed runs. A relevant amount of dissolved phenolics were detected … Show more

“…Figure 3D shows the photocatalytic hydrogen evolution under the AMF and other conditions. As shown in Figure 4, the temperature of T/NF‐float system increased to 70°C in few minutes under the AMF condition, thus greatly improving the hydrogen evolution rate 28 . The hydrogen evolution rate was 104.3 μmol h −1 under the AMF condition, 2.3 times higher than that of T/NF‐float system without adding AMF, and 12.2 times of that of the triphase, that is, T/NF‐sink system.…”

“…As shown in Figure 4, the temperature of T/NF-float system increased to 70 C in few minutes under the AMF condition, thus greatly improving the hydrogen evolution rate. 28 The hydrogen evolution rate was 104.3 μmol h À1 under the AMF condition, 2.3 times higher than that of T/NF-float system without adding AMF, and 12.2 times of that of the triphase, that is, T/NF-sink system. Significantly, in comparison to the similar reaction that was set at 70 C yet without AMF, the magnetic-thermal coupling effect is obvious.…”

Decoupling gaseous hydrogen production from liquid water using a magnetic‐photo‐thermal coupling reactor

“…Figure 3D shows the photocatalytic hydrogen evolution under the AMF and other conditions. As shown in Figure 4, the temperature of T/NF‐float system increased to 70°C in few minutes under the AMF condition, thus greatly improving the hydrogen evolution rate 28 . The hydrogen evolution rate was 104.3 μmol h −1 under the AMF condition, 2.3 times higher than that of T/NF‐float system without adding AMF, and 12.2 times of that of the triphase, that is, T/NF‐sink system.…”

“…As shown in Figure 4, the temperature of T/NF-float system increased to 70 C in few minutes under the AMF condition, thus greatly improving the hydrogen evolution rate. 28 The hydrogen evolution rate was 104.3 μmol h À1 under the AMF condition, 2.3 times higher than that of T/NF-float system without adding AMF, and 12.2 times of that of the triphase, that is, T/NF-sink system. Significantly, in comparison to the similar reaction that was set at 70 C yet without AMF, the magnetic-thermal coupling effect is obvious.…”

Decoupling gaseous hydrogen production from liquid water using a magnetic‐photo‐thermal coupling reactor

“…In this framework different polyols and sugars have been used as feedstock for aqueous phase reforming, such as ethylene glycol, glycerol, xylitol, fructose and glucose [6,8,11,12,15,16,17,18,19] . The latter is of particular interest as it can be directly obtained from cellulose by hydrolysis [20,21,22,23] .…”

Molecular Ruthenium Cyclopentadienone Bifunctional Catalysts for the Conversion of Sugar Platforms to Hydrogen

“…Methanol (CH 3 OH) as a safe and inexpensive liquid organic hydrogen storage carrier with high H 2 capacity (12.6 wt%), is considered as an ideal candidate toward addressing the storage and transportation issues for H 2 energy utilization 5 . Thermocatalytic aqueous‐phase reforming of methanol (APRM) with production of 3 mol of H 2 from 1 mol of CH 3 OH is an attractive process (Equation ()) due to green and cheap reforming mediator (H 2 O) and the relatively milder conditions (200–250°C, 1.5–5.0 MPa), 4,6 thus promoting economic efficiency. …”

“…Hydrogen (H 2 ) production, storage and transportation as the core of novel H 2 economy have gained extensive attentions in both industry and academia 1–4 . Methanol (CH 3 OH) as a safe and inexpensive liquid organic hydrogen storage carrier with high H 2 capacity (12.6 wt%), is considered as an ideal candidate toward addressing the storage and transportation issues for H 2 energy utilization 5 .…”

Metal‐organic framework stabilizes Cu₇S₄‐wrapped Cu₂O heterostructure for photothermal‐promoted methanol/water reforming into hydrogen