Investigating the Effect of Cerium-Promoted Ni-based Catalysts for Waste Polyolefin Hydrocracking

• Alexander Bregvadze, Chemical Engineering, University of Delaware

• Dionisios Vlachos, Chemical Engineering, University of Delaware
• Jessie Sun, Chemical Engineering, University of Delaware

Plastics are used due to their low cost and chemical stability, but their prevalent use has led to unsustainable disposal methods; therefore, more sustainable solutions are needed to address the growing issue of plastic waste. Polyolefins (PO), such as low-density polyethylene (LDPE) plastic bags, constitute 57% of total municipal solid waste¹ making them prime candidates for chemical upcycling. One promising method for upcycling PO is through hydrocracking which uses a bifunctional metal/zeolite catalyst to deconstruct long polymer chains into alkanes like naphtha.¹

Previous works have utilized noble metals (Pt/Ru) supported on an acidic support including zeolites (ZSM-5/ Beta) to degrade POs into naphtha. Vance, B. et. al revealed the use of nickel, an earth-abundant metal, which is generally cheaper in comparison to noble metals, deposited on Beta Zeolite (Ni/BEA) catalyst.² The 5Ni/BEA catalyst, though active, requires high hydrogen pressure and is highly susceptible to coke formation, thereby reducing its extended activity and reuse.² Additionally, Wang, H. et al demonstrated that adding cerium (Ce) to a PtSn-based catalyst minimized coke formation and enhanced catalyst activity by increasing the concentration of BA sites for improved cracking efficiency.³ Therefore, we hypothesize that incorporating Ce into 5Ni/BEA would similarly decrease coke formation and improve catalyst performance.

Initial results indicate that increasing the incorporated Ce weight % in 5Ni/BEA enhances the conversion of LDPE without affecting the desired product selectivity for naphtha. Specifically, the catalyst with 20% Ce (5Ni20Ce/BEA) achieved the highest deconstruction with a product (C₁-C₁₆) yield of 86.8% whereas 5Ni/BEA achieved only 58.9%. Thermogravimetric Analysis (TGA) of the spent catalyst reveals lower mass loss attributed to the deposition of organic residues and coke species with the incorporation of Ce to Ni/BEA. This suggests Ce minimizes active site coking and rationalizes the higher catalytic performance. The 5Ni20Ce/BEA exhibits a lower coke content with a total mass loss of 19.8% compared to 5NiBEA 25.5%.

[1] Dong, Z., Chen, W., Xu, K., Liu, Y., Wu, J., & Zhang, F. (2022). Understanding the Structure–Activity Relationships in Catalytic Conversion of Polyolefin Plastics by Zeolite-Based Catalysts: A Critical Review. ACS Catalysis, 12(24), 14882–14901. https://doi.org/10.1021/acscatal.2c04915

[2] Vance, B. C., Yuliu, Z., Najmi, S., Selvam, E., Granite, J. E., Yu, K., Ierapetritou, M. G., & Vlachos, D. G. (2024). Unlocking naphtha from polyolefins using Ni-based hydrocracking catalysts. Chemical Engineering Journal, 487, 150468. https://doi.org/https://doi.org/10.1016/j.cej.2024.150468

[3] Wang, H., Yoskamtorn, T., Zheng, J., Ho, P.-L., Ng, B., & Tsang, S. C. E. (2023). Ce-Promoted PtSn-Based Catalyst for Hydrocracking of Polyolefin Plastic Waste into High Yield of Gasoline-Range Products. ACS Catalysis, 13(24), 15886–15898. https://doi.org/10.1021/acscatal.3c03996Top of Form