改性NaY分子筛吸附脱除模拟燃油中喹啉的理论研究

Theoretical study on the adsorption and removal of quinoline from simulated fuel by modified NaY zeolite

  • 摘要: 利用离子交换法改性NaY分子筛,制备了AgY、CuY、ZnY和CrY分子筛,采用X射线衍射(XRD)和傅里叶红外光谱(FT-IR)进行表征,并用于吸附脱除模拟燃油中的喹啉。实验结果表明,改性后分子筛的XRD谱图均出现Y型分子筛特征峰,晶格常数均有所下降;模拟计算五种分子筛的XRD谱图并与实验测得的XRD谱图对比,两者2θ误差值小于0.1°,验证了模拟计算Y分子筛模型选取的合理性;AgY、CuY、ZnY分子筛红外谱图在1024 cm−1吸收峰处发生红移,CrY发生蓝移,改性后Y分子筛1147 cm−1处吸收峰的消失或增强。AgY、CuY、ZnY和CrY吸附喹啉的性能明显高于NaY分子筛,且吸附能力大小为AgY>CrY>CuY>ZnY。为从微观分子水平更好地研究分子筛吸附脱氮机理,以密度泛函理论(DFT)为基础,采用Materials Studio模拟软件模拟计算喹啉在五种分子筛上的吸附能、静电势、ESP电荷差值以及Mulliken布居分析等吸附参数。吸附能绝对值、ESP电荷差值、Mulliken布居比值绝对值的大小顺序均为AgY>CrY>CuY>ZnY,与实验结果完美吻合。静电势图表明吸附体系的电子传递路径总体为:喹啉分子上的H→喹啉内部的C→喹啉中的N→分子筛团簇的过渡金属离子M→与M成键的O→整个团簇骨架,同时部分电子从喹啉分子下端靠近团簇的H→分子筛团簇六元环骨架外侧的O;Mulliken布居分析说明改性分子筛吸附脱氮机理主要是σ给予键和d-π*反馈键的共同作用,且以σ给予键为主。

     

    Abstract: A large amount of nitrogen oxides in the atmosphere posed a serious threat to the environment and the health of animals and plants. Nitrogen compounds in diesel were one of the main sources of nitrogen oxides in the atmosphere. Adsorption denitrification technology had attracted widespread attention because it could efficiently remove nitrogen compounds from diesel under mild conditions. NaY zeolite had been widely used in the petroleum field due to its excellent cation exchange capacity and selectivity. In response to national environmental protection policies and to meet increasingly stringent diesel quality standards, our research group successfully prepared AgY, CuY, ZnY and CrY zeolites by replacing transition metal ions Ag+, Cu2+, Zn2+ and Cr3+ with the compensating cation Na+ on NaY zeolite through ion exchange method based on the cation exchange characteristics of NaY zeolite. This further improved the adsorption effect of Y zeolite on nitrogen compounds in diesel. AgY, CuY, ZnY, CrY and NaY were characterized using X-ray diffraction (XRD) and Fourier transform infrared spectroscopy (FT-IR), and were used for adsorption and removal of quinoline from simulated fuel. The experimental results showed that the XRD patterns of the modified zeolite exhibited characteristic peaks of Y-shaped zeolite, and the lattice constants decreased slightly; The FT-IR spectrum of AgY, CuY and ZnY zeolites showed a red shift at the 1024 cm−1 absorption peak, and a blue shift for CrY. The changes in the lattice constants and the absorption peaks of the FT-IR spectrum indirectly indicated that the transition metal ions were successfully replaced with Na+ on the zeolite framework. It was AgY>CrY>CuY>ZnY about the adsorption capacity of AgY, CuY, ZnY and CrY for quinoline, the adsorption capacity of four zeolites was significantly higher than that of NaY zeolite. In order to better study the nitrogen removal mechanism of zeolite adsorption at the micro molecular level, materials studio simulation software was used to calculate the relevant parameters. The XRD patterns of five zeolites were drawn by simulation calculation, and the 2θ error between the simulated and experimentally measured XRD spectra was less than 0.1°, which verified the rationality of the unit cell model; In order to improve the calculation efficiency, the S site in the unit cell was used as the reactive active site, and the 12T cluster was intercepted instead of the whole for subsequent theoretical calculation. The absorption peak of modified Y zeolite at 1147 cm−1 of the antisymmetric stretching vibration of the double six membered ring between the attributed tetrahedrons disappears or strengthens, indicating that the compensation ions on the six membered ring had been replaced by transition metal ions, affecting the original vibration frequency of the six membered ring. The change of this peak further verified the rationality of the selection of the 12T cluster model. Based on density functional theory (DFT), adsorption parameters such as adsorption energy, electrostatic potential, ESP charge difference, and Mulliken population analysis of quinoline on 12T clusters of five zeolites were simulated and calculated. The order of absolute values of adsorption energy, ESP charge difference and Mulliken population ratio was AgY>CrY>CuY>ZnY, which was in perfect agreement with the experimental results. In addition, the ESP analysis showed that the electron transfer path was as follows: H in the quinoline→C inside the quinoline→N in the quinoline→transition metal ion M of the zeolite cluster→O bonded with M→the entire cluster framework, while some electrons from the lower end of the quinoline molecule close to the cluster of the H→O in the outer part of the six-membered ring framework of zeolite clusters; Mulliken population analysis revealed that the adsorption and denitrification mechanism of modified zeolite was primarily the combined effect of σ-donation and d-π* backdonation bonds, with the σ-donation bond being the predominant one.

     

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