Muhammad Yaseen, Rahman Ata Ur, Rashid Haroon Ur, Sahibzada Maria, Subhan Sidra, Tong Zhangfa
School of Chemistry and Chemical Engineering, Key Laboratory of Petrochemical Resource Processing and Process Intensification Technology, Guangxi University Guangxi 530004 P. R. China
Institute of Chemical Sciences, University of Peshawar Peshawar 25120 KP Pakistan.
RSC Adv. 2019 Apr 2;9(18):10371-10385. doi: 10.1039/c9ra00095j. eCollection 2019 Mar 28.
Sulfur compounds in fuel oils are a major source of atmospheric pollution. This study is focused on the hydrodesulfurization (HDS) of dibenzothiophene (DBT) the coupled application of 0.5 wt% Pd-loaded Co-Mo/AlO and Ni-Mo/AlO catalysts with ionic liquids (ILs) at ambient temperature (120 °C) and pressure (1 MPa H). The enhanced HDS activity of the solid catalysts coupled with [BMIM]BF, [(CH)N]Cl, [EMIM]AlCl, and [(CH)(CH)P]Br was credited to the synergism between hydrogenation by the former and extractive desulfurization and better H transport by the latter, which was confirmed by DFT simulation. The Pd-loaded catalysts ranked highest by activity Pd-Ni-Mo/AlO > Pd-Co-Mo/AlO > Ni-Mo/AlO > Co-Mo/AlO. With mild experimental conditions of 1 MPa H pressure and 120 °C temperature and an oil : IL ratio of 10 : 3.3, DBT conversion was enhanced from 21% (by blank Ni-Mo/AlO) to 70% by Pd-Ni-Mo/AlO coupled with [(CH)(CH)P]Br. The interaction of polarizable delocalized bonds (in DBT) and van der Waals forces influenced the higher solubility in ILs and hence led to higher DBT conversion. The IL was recycled four times with minimal loss of activity. Fresh and spent catalysts were characterized by FESEM, ICP-MS, EDX, XRD, XPS and BET surface area techniques. GC-MS analysis revealed biphenyl as the major HDS product. This study presents a considerable advance to the classical HDS processes in terms of mild operating conditions, cost-effectiveness, and simplified mechanization, and hence can be envisaged as an alternative approach for fuel oil processing.
燃料油中的硫化合物是大气污染的主要来源。本研究聚焦于二苯并噻吩(DBT)的加氢脱硫(HDS),即在环境温度(120℃)和压力(1MPa H)下,将负载0.5wt% Pd的Co-Mo/Al₂O₃和Ni-Mo/Al₂O₃催化剂与离子液体(ILs)联合应用。负载Pd的固体催化剂与[BMIM]BF₄、[(CH₃)₃N]Cl、[EMIM]AlCl₄和[(CH₃)(C₂H₅)P]Br联合使用时,其HDS活性增强,这归因于前者的加氢作用与后者的萃取脱硫及更好的氢传输之间的协同作用,密度泛函理论(DFT)模拟证实了这一点。负载Pd的催化剂活性最高,顺序为Pd-Ni-Mo/Al₂O₃ > Pd-Co-Mo/Al₂O₃ > Ni-Mo/Al₂O₃ > Co-Mo/Al₂O₃。在1MPa H压力、120℃温度以及油与离子液体比例为10∶3.3的温和实验条件下,DBT转化率从(空白Ni-Mo/Al₂O₃时的)21%提高到了Pd-Ni-Mo/Al₂O₃与[(CH₃)(C₂H₅)P]Br联合使用时的70%。可极化离域键(在DBT中)与范德华力的相互作用影响了其在离子液体中的更高溶解度,从而导致更高的DBT转化率。离子液体循环使用了4次,活性损失极小。采用场发射扫描电子显微镜(FESEM)、电感耦合等离子体质谱(ICP-MS)、能谱仪(EDX)、X射线衍射仪(XRD)、X射线光电子能谱仪(XPS)和比表面积分析仪(BET)等技术对新鲜催化剂和使用过的催化剂进行了表征。气相色谱-质谱联用(GC-MS)分析表明,联苯是主要的HDS产物。本研究在温和的操作条件、成本效益和简化的机械化方面相对于传统的HDS工艺有了显著进展,因此可被视为燃料油加工的一种替代方法。
