Sustainable production of dimethyl-protected cyclic lysine over Pd/m-Al2O3-Si catalysts and its application in synthesis of antibacterial nylon‑6 copolymers

•Pd/m-Al2O3-Si catalyst exhibited high efficiency in converting α-amino-ε-caprolactam (α-ACL) to dimethyl-protected cyclic lysine (DMCL).•The lack of Brönsted acid sites on Pd/m-Al2O3-Si surface facilitated the formation of DMCL and suppressed undesirable reaction process.•Pd/m-Al2O3-Si catalyst wit...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2023-05, Vol.463, p.142504, Article 142504
Main Authors: Liu, Kangyu, Shao, Bingzhang, Liu, Haichao, He, Jinlong, Zheng, Aiguo, Li, Genghong, Zheng, Bo, Li, Zeyang, Liu, Wei, Li, Xuefeng, Zong, Baoning
Format: Article
Language:English
Subjects:
Brönsted acid sites
Dimethyl-protected cyclic lysine
microspherical Pd catalysts
Nylon‑6 copolymers
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Summary:•Pd/m-Al2O3-Si catalyst exhibited high efficiency in converting α-amino-ε-caprolactam (α-ACL) to dimethyl-protected cyclic lysine (DMCL).•The lack of Brönsted acid sites on Pd/m-Al2O3-Si surface facilitated the formation of DMCL and suppressed undesirable reaction process.•Pd/m-Al2O3-Si catalyst with microspherical morphology performed excellent stability and physical strength during the catalytic process.•The nylon‑6 copolymers produced from the as-synthesized DMCL exhibited a great potential in the synthesis of self-cleaning antibacterial materials. Antibacterial monomers are prerequisites for synthesizing antibacterial polymers, especially during the current COVID-19 pandemic. Dimethyl-protected cyclic lysine (DMCL) is a promising functional monomer for nylon-6 based self-cleaning antibacterial polymers. However, the production of DMCL still faces formidable challenges, such as harsh reaction conditions and low catalyst activities. In this study, we developed a Pd/m-Al2O3-Si catalyst, which exhibited high efficiency in converting α-amino-ε-caprolactam (α-ACL) to DMCL, affording a yield of as high as 97.1% at 100 °C and 1 MPa H2. The lack of Brönsted acid sites on the catalyst surface facilitated the formation of DMCL and suppressed undesirable hydrolysis or cracking by-products from the lactam-based reactant. The recycled experiments showed that Pd/m-Al2O3-Si performed excellent stability and physical strength with essentially no damage to its microspheres after the reaction. The nylon‑6 copolymers produced from the as-synthesized DMCL exhibited similar structure and thermal stability with pure nylon-6, showing great potential in synthesizing the self-cleaning antibacterial polymers. This work provides a sustainable and efficient method for producing DMCL and other lysine-based antibacterial monomers, showing a great prospect for the utilization of bio-based chemicals in synthesizing functional polymers.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2023.142504