Mild reductive catalytic depolymerization of lignin in a continuous flow reactor using a Cu-enhanced Pd catalyst
- Author
- Tibo De Saegher (UGent) , Jonas Elmroth Nordlander, Filip Hallböök, Boyana Atanasova (UGent) , Pieter Vermeir (UGent) , Kevin Van Geem (UGent) , Jeriffa De Clercq (UGent) , An Verberckmoes (UGent) , Christian Hulteberg and Jeroen Lauwaert (UGent)
- Organization
- Project
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- Unleashing lignin valorization potential via consecutive mild soda extraction, mixed metal oxide catalyzed hydrogenolysis and high resolution 2D chromatography.
- Unravelling the subtle nature of lignin depolymerization using online coupled GPC-comprehensive 2DGC equipped with a versatile pyrolysis interfacing
- Abstract
- Mild reductive catalytic depolymerization (MRCD) of lignin offers a sustainable route to produce functionalized aromatic compounds. However, the economic viability is hindered by the need for expensive palladium (Pd) catalysts and the limited exploration of continuous flow reactors (CFRs), which are essential to achieve an adequate production scale. This study examines the impact of partial replacement of Pd with copper (Cu) on the performance, selectivity, active site characteristics, and deactivation of a γ-Al2O3 supported Pd catalyst in MRCD of lignin using a CFR. Despite containing 49 % less Pd, the PdCu catalyst achieves the same depolymerization degree as the Pd catalyst over 200 min of time on stream. During the reaction, metallic Pd is formed within the Pd catalyst and both a smaller (unordered) and larger (ordered FCC) metallic PdCu phase within the PdCu catalyst. The enhanced performance of the PdCu catalyst is attributed to synergistic effects between Pd and Cu and presence of differently sized metallic phases. A minimal impact of Cu on the selectivity, even in monomer yields, was observed. For both catalysts, the primary cause of deactivation is the hydration of the γ-Al2O3 support to boehmite, leading to loss of its acidity and morphological changes. Metal leaching and poisoning are insignificant, while nanoparticle growth likely arises from the reduction of the metallic phases during reaction. Only a very small amount of coke deposition is observed. Overall, the cost-effective partial replacement of Pd with of Cu forms metallic PdCu alloys during the reaction, enhancing activity without adversely affecting selectivity or deactivation.
- Keywords
- Heterogeneous catalysis, Continuous flow reactor, Bimetallic nanoparticle catalysts, Catalyst deactivation, Depolymerization, Lignin, Bio-aromatics, GAMMA-ALUMINA, PALLADIUM, DISPERSION, OXIDATION
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Citation
Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01JJXWP38GGQANJCFC4D2NPSTP
- MLA
- De Saegher, Tibo, et al. “Mild Reductive Catalytic Depolymerization of Lignin in a Continuous Flow Reactor Using a Cu-Enhanced Pd Catalyst.” CHEMICAL ENGINEERING JOURNAL ADVANCES, vol. 22, 2025, doi:10.1016/j.ceja.2025.100710.
- APA
- De Saegher, T., Elmroth Nordlander, J., Hallböök, F., Atanasova, B., Vermeir, P., Van Geem, K., … Lauwaert, J. (2025). Mild reductive catalytic depolymerization of lignin in a continuous flow reactor using a Cu-enhanced Pd catalyst. CHEMICAL ENGINEERING JOURNAL ADVANCES, 22. https://doi.org/10.1016/j.ceja.2025.100710
- Chicago author-date
- De Saegher, Tibo, Jonas Elmroth Nordlander, Filip Hallböök, Boyana Atanasova, Pieter Vermeir, Kevin Van Geem, Jeriffa De Clercq, An Verberckmoes, Christian Hulteberg, and Jeroen Lauwaert. 2025. “Mild Reductive Catalytic Depolymerization of Lignin in a Continuous Flow Reactor Using a Cu-Enhanced Pd Catalyst.” CHEMICAL ENGINEERING JOURNAL ADVANCES 22. https://doi.org/10.1016/j.ceja.2025.100710.
- Chicago author-date (all authors)
- De Saegher, Tibo, Jonas Elmroth Nordlander, Filip Hallböök, Boyana Atanasova, Pieter Vermeir, Kevin Van Geem, Jeriffa De Clercq, An Verberckmoes, Christian Hulteberg, and Jeroen Lauwaert. 2025. “Mild Reductive Catalytic Depolymerization of Lignin in a Continuous Flow Reactor Using a Cu-Enhanced Pd Catalyst.” CHEMICAL ENGINEERING JOURNAL ADVANCES 22. doi:10.1016/j.ceja.2025.100710.
- Vancouver
- 1.De Saegher T, Elmroth Nordlander J, Hallböök F, Atanasova B, Vermeir P, Van Geem K, et al. Mild reductive catalytic depolymerization of lignin in a continuous flow reactor using a Cu-enhanced Pd catalyst. CHEMICAL ENGINEERING JOURNAL ADVANCES. 2025;22.
- IEEE
- [1]T. De Saegher et al., “Mild reductive catalytic depolymerization of lignin in a continuous flow reactor using a Cu-enhanced Pd catalyst,” CHEMICAL ENGINEERING JOURNAL ADVANCES, vol. 22, 2025.
@article{01JJXWP38GGQANJCFC4D2NPSTP,
abstract = {{Mild reductive catalytic depolymerization (MRCD) of lignin offers a sustainable route to produce functionalized aromatic compounds. However, the economic viability is hindered by the need for expensive palladium (Pd) catalysts and the limited exploration of continuous flow reactors (CFRs), which are essential to achieve an adequate production scale. This study examines the impact of partial replacement of Pd with copper (Cu) on the performance, selectivity, active site characteristics, and deactivation of a γ-Al2O3 supported Pd catalyst in MRCD of lignin using a CFR. Despite containing 49 % less Pd, the PdCu catalyst achieves the same depolymerization degree as the Pd catalyst over 200 min of time on stream. During the reaction, metallic Pd is formed within the Pd catalyst and both a smaller (unordered) and larger (ordered FCC) metallic PdCu phase within the PdCu catalyst. The enhanced performance of the PdCu catalyst is attributed to synergistic effects between Pd and Cu and presence of differently sized metallic phases. A minimal impact of Cu on the selectivity, even in monomer yields, was observed. For both catalysts, the primary cause of deactivation is the hydration of the γ-Al2O3 support to boehmite, leading to loss of its acidity and morphological changes. Metal leaching and poisoning are insignificant, while nanoparticle growth likely arises from the reduction of the metallic phases during reaction. Only a very small amount of coke deposition is observed. Overall, the cost-effective partial replacement of Pd with of Cu forms metallic PdCu alloys during the reaction, enhancing activity without adversely affecting selectivity or deactivation.}},
articleno = {{100710}},
author = {{De Saegher, Tibo and Elmroth Nordlander, Jonas and Hallböök, Filip and Atanasova, Boyana and Vermeir, Pieter and Van Geem, Kevin and De Clercq, Jeriffa and Verberckmoes, An and Hulteberg, Christian and Lauwaert, Jeroen}},
issn = {{2666-8211}},
journal = {{CHEMICAL ENGINEERING JOURNAL ADVANCES}},
keywords = {{Heterogeneous catalysis,Continuous flow reactor,Bimetallic nanoparticle catalysts,Catalyst deactivation,Depolymerization,Lignin,Bio-aromatics,GAMMA-ALUMINA,PALLADIUM,DISPERSION,OXIDATION}},
language = {{eng}},
pages = {{7}},
title = {{Mild reductive catalytic depolymerization of lignin in a continuous flow reactor using a Cu-enhanced Pd catalyst}},
url = {{http://doi.org/10.1016/j.ceja.2025.100710}},
volume = {{22}},
year = {{2025}},
}
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