Synthesis of NaY zeolite from a submolten depolymerized perlite: Alkalinity effect and crystallization kinetics

doi:10.1016/j.cjche.2024.03.009

中国化学工程学报 ›› 2024, Vol. 70 ›› Issue (6): 130-138.DOI: 10.1016/j.cjche.2024.03.009

Synthesis of NaY zeolite from a submolten depolymerized perlite: Alkalinity effect and crystallization kinetics

Yanli Qu^1,2, Peng Dong³, Li Yang¹, Yuanyuan Yue^3,4, Haoliang Wang¹, Jingcai Cheng¹, Chao Yang^1,2

1. CAS Key Laboratory of Green Process and Engineering, State Key Laboratory of Petroleum Molecular & Process Engineering, Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, China;
2. School of Chemical Engineering, University of Chinese Academy of Sciences, Beijing 100190, China;
3. Qingyuan Innovation Laboratory, Quanzhou 362801, China;
4. National Engineering Research Center of Chemical Fertilizer Catalyst, College of Chemical Engineering, Fuzhou University, Fuzhou 350108, China

收稿日期:2024-01-21 修回日期:2024-03-14 出版日期:2024-06-28 发布日期:2024-08-05
通讯作者: Jingcai Cheng,E-mail:jccheng@ipe.ac.cn
基金资助:
Financial supports from National Natural Science Foundation of China (21938009, 22308358, 22208346, 22078332), National Key Research and Development Program (2022YFC3902701), Ningxia Natural Science Foundation (2021AAC01002), the External Cooperation Program of BIC, Chinese Academy of Sciences (122111KYSB20190032) and CAS Project for Young Scientists in Basic Research (YSBR-038) are gratefully acknowledged.

Synthesis of NaY zeolite from a submolten depolymerized perlite: Alkalinity effect and crystallization kinetics

Yanli Qu^1,2, Peng Dong³, Li Yang¹, Yuanyuan Yue^3,4, Haoliang Wang¹, Jingcai Cheng¹, Chao Yang^1,2

1. CAS Key Laboratory of Green Process and Engineering, State Key Laboratory of Petroleum Molecular & Process Engineering, Institute of Process Engineering, Chinese Academy of Sciences, Beijing 100190, China;
2. School of Chemical Engineering, University of Chinese Academy of Sciences, Beijing 100190, China;
3. Qingyuan Innovation Laboratory, Quanzhou 362801, China;
4. National Engineering Research Center of Chemical Fertilizer Catalyst, College of Chemical Engineering, Fuzhou University, Fuzhou 350108, China

Received:2024-01-21 Revised:2024-03-14 Online:2024-06-28 Published:2024-08-05
Contact: Jingcai Cheng,E-mail:jccheng@ipe.ac.cn
Supported by:
Financial supports from National Natural Science Foundation of China (21938009, 22308358, 22208346, 22078332), National Key Research and Development Program (2022YFC3902701), Ningxia Natural Science Foundation (2021AAC01002), the External Cooperation Program of BIC, Chinese Academy of Sciences (122111KYSB20190032) and CAS Project for Young Scientists in Basic Research (YSBR-038) are gratefully acknowledged.

摘要/Abstract

摘要： NaY zeolites are synthesized using submolten salt depolymerized natural perlite mineral as the main silica and alumina sources in a 0.94 L stirred crystallizer. Effects of alkalinity ranging from 0.38 to 0.55 (n(Na₂O)/n(SiO₂)) on the relative crystallinity, textural properties and crystallization kinetics were investigated. The results show that alkalinity exerts a nonmonotonic influence on the relative crystallinity and textural properties, which exhibit a maximum at the alkalinity of 0.43. The nucleation kinetics are studied by fitting the experimental data of relative crystallinity with the Gualtieri model. It is shown that the nucleation rate constant increases with increasing alkalinity, while the duration period of nucleation decreases with increasing alkalinity. For n(Na₂O)/n(SiO₂) ratios ranging from 0.38 to 0.55, the as-synthesized NaY zeolites exhibit narrower crystal size distributions with the increase in alkalinity. The growth rates determined from the variations of average crystal size with time are 51.09, 157.50, 46.17 and 24.75 nm·h^-1, respectively. It is found that the larger average crystal sizes at the alkalinity of 0.38 and 0.43 are attributed to the dominant role of crystal growth over nucleation. Furthermore, the combined action of prominent crystal growth and the longer duration periods of nucleation at the alkalinity of 0.38 and 0.43 results in broader crystal size distributions. The findings demonstrate that control of the properties of NaY zeolite and the crystallization kinetics can be achieved by conducting the crystallization process in an appropriate range of alkalinity of the reaction mixture.

关键词: NaY zeolite, Submolten salt depolymerized perlite, Alkalinity, Crystallization kinetics

Abstract: NaY zeolites are synthesized using submolten salt depolymerized natural perlite mineral as the main silica and alumina sources in a 0.94 L stirred crystallizer. Effects of alkalinity ranging from 0.38 to 0.55 (n(Na₂O)/n(SiO₂)) on the relative crystallinity, textural properties and crystallization kinetics were investigated. The results show that alkalinity exerts a nonmonotonic influence on the relative crystallinity and textural properties, which exhibit a maximum at the alkalinity of 0.43. The nucleation kinetics are studied by fitting the experimental data of relative crystallinity with the Gualtieri model. It is shown that the nucleation rate constant increases with increasing alkalinity, while the duration period of nucleation decreases with increasing alkalinity. For n(Na₂O)/n(SiO₂) ratios ranging from 0.38 to 0.55, the as-synthesized NaY zeolites exhibit narrower crystal size distributions with the increase in alkalinity. The growth rates determined from the variations of average crystal size with time are 51.09, 157.50, 46.17 and 24.75 nm·h^-1, respectively. It is found that the larger average crystal sizes at the alkalinity of 0.38 and 0.43 are attributed to the dominant role of crystal growth over nucleation. Furthermore, the combined action of prominent crystal growth and the longer duration periods of nucleation at the alkalinity of 0.38 and 0.43 results in broader crystal size distributions. The findings demonstrate that control of the properties of NaY zeolite and the crystallization kinetics can be achieved by conducting the crystallization process in an appropriate range of alkalinity of the reaction mixture.

Key words: NaY zeolite, Submolten salt depolymerized perlite, Alkalinity, Crystallization kinetics

Yanli Qu, Peng Dong, Li Yang, Yuanyuan Yue, Haoliang Wang, Jingcai Cheng, Chao Yang. Synthesis of NaY zeolite from a submolten depolymerized perlite: Alkalinity effect and crystallization kinetics[J]. 中国化学工程学报, 2024, 70(6): 130-138.

参考文献

[1] Z.P. Wang, J.H. Yu, R.R. Xu, Needs and trends in rational synthesis of zeolitic materials, Chem. Soc. Rev. 41 (5) (2012) 1729-1741.
[2] Y. Li, J.H. Yu, New stories of zeolite structures: their descriptions, determinations, predictions, and evaluations, Chem. Rev. 114 (14) (2014) 7268-7316.
[3] C.G. Li, M. Moliner, A. Corma, Building zeolites from precrystallized units: nanoscale architecture, Angew. Chem. Int. Ed Engl. 57 (47) (2018) 15330-15353.
[4] X.Y. Li, H. Han, N. Evangelou, N.J. Wichrowski, P. Lu, W.Q. Xu, S.J. Hwang, W.Y. Zhao, C.S. Song, X.W. Guo, A. Bhan, I.G. Kevrekidis, M. Tsapatsis, Machine learning-assisted crystal engineering of a zeolite, Nat. Commun. 14 (1) (2023) 3152.
[5] D. Verboekend, N. Nuttens, R. Locus, J. Van Aelst, P. Verolme, J.C. Groen, J. Perez-Ramirez, B.F. Sels, Synthesis, characterisation, and catalytic evaluation of hierarchical faujasite zeolites: milestones, challenges, and future directions, Chem. Soc. Rev. 45 (12) (2016) 3331-3352.
[6] B. Meng, S.Y. Ren, X.Y. Liu, L. Zhang, Q.X. Hu, J.J. Wang, Q.X. Guo, B.J. Shen, Synthesis of USY zeolite with a high mesoporous content by introducing Sn and enhanced catalytic performance, Ind. Eng. Chem. Res. 59 (13) (2020) 5712-5719.
[7] D.L. Zhu, L.Y. Wang, W.N. Zhang, D. Fan, J.Z. Li, W.H. Cui, S.J. Huang, S.T. Xu, P. Tian, Z.M. Liu, Realizing fast synthesis of high-silica zeolite Y with remarkable catalytic performance, Angew. Chem. Int. Ed Engl. 61 (23) (2022) e202117698.
[8] G. Garcia, E. Cardenas, S. Cabrera, J. Hedlund, J. Mouzon, Synthesis of zeolite Y from diatomite as silica source, Microporous Mesoporous Mater. 219 (2016) 29-37.
[9] J.Q. Wang, Y.X. Huang, Y.M. Pan, J.X. Mi, New hydrothermal route for the synthesis of high purity nanoparticles of zeolite Y from Kaolin and quartz, Microporous Mesoporous Mater. 232 (2016) 77-85.
[10] W.N. Wang, S.S. Kong, X.X. Zhou, D.L. Yuan, H. Li, S.Y. Ren, B.J. Shen, Perlite templated Y zeolite assembly and its potential as an efficient catalytic cracking catalyst, Microporous Mesoporous Mater. 243 (2017) 130-134.
[11] M. Feng, Z.R. Kou, C.Y. Tang, Z.M. Shi, Y.C. Tong, K.W. Zhang, Recent progress in synthesis of zeolite from natural clay, Appl. Clay Sci. 243 (2023) 107087.
[12] T.S. Li, H.Y. Liu, Y. Fan, P. Yuan, G. Shi, X.T. Bi, X.J. Bao, Synthesis of zeolite Y from natural aluminosilicate minerals for fluid catalytic cracking application, Green Chem. 14 (12) (2012) 3255.
[13] J.B. Yang, T.S. Li, X.J. Bao, Y.Y. Yue, H.Y. Liu, Mesoporogen-free synthesis of hierarchical sodalite as a solid base catalyst from sub-molten salt-activated aluminosilicate, Particuology 48 (2020) 48-54.
[14] Y.Y. Yue, X.X. Guo, T. Liu, H.Y. Liu, T.H. Wang, P. Yuan, H.B. Zhu, Z.S. Bai, X.J. Bao, Template free synthesis of hierarchical porous zeolite Beta with natural Kaolin clay as alumina source, Microporous Mesoporous Mater. 293 (2020) 109772.
[15] X.L. Chen, Y. Wang, C. Wang, J.D. Xu, T.S. Li, Y.Y. Yue, X.T. Bi, L.L. Jiang, X.J. Bao, Synthesis of NaA zeolite via the mesoscale reorganization of submolten salt depolymerized Kaolin: a mechanistic study, Chem. Eng. J. 454 (2023) 140243.
[16] P. Dong, J.Y. Zhang, T.S. Li, C. Wang, J.D. Xu, T.H. Wang, Y.Y. Yue, L.L. Jiang, X.J. Bao, Dealumination of Y zeolite through an economic and eco-friendly defect-engineering strategy, AlChE. J. 69 (9) (2023) e18183.
[17] M. Choi, K. Na, J. Kim, Y. Sakamoto, O. Terasaki, R. Ryoo, Stable single-unit-cell nanosheets of zeolite MFI as active and long-lived catalysts, Nature 461 (7261) (2009) 246-249.
[18] Q. Cui, Y. Zhou, Q. Wei, X. Tao, G. Yu, Y. Wang, J. Yang, Role of the zeolite crystallite size on hydrocracking of vacuum gas oil over NiW/Y-ASA catalysts, Energy & Fuels, 26 (2012) 4664-4670.
[19] S. Hu, J. Shan, Q. Zhang, Y. Wang, Y.S. Liu, Y.J. Gong, Z.J. Wu, T. Dou, Selective formation of propylene from methanol over high-silica nanosheets of MFI zeolite, Appl. Catal. A Gen. 445-446 (2012) 215-220.
[20] D. Karami, S. Rohani, The effect of particle-size reduction of zeolite Y on catalytic cracking of bulky hydrocarbons, Petrol. Sci. Technol. 31 (16) (2013) 1625-1632.
[21] X.J. Dai, Y. Cheng, T.T. Liu, L.J. Mao, R.H. Kang, Q. Wei, Y.S. Zhou, Synthesis of small-crystal Y zeolites via regulating Na₂O/Al₂O₃ and superior catalytic performance of corresponding NiWS-supported catalysts for hydrocracking of naphthalene, New J. Chem. 47 (43) (2023) 20157-20170.
[22] Q. Li, D. Creaser, J. Sterte, The nucleation period for TPA-silicalite-1 crystallization determined by a two-stage varying-temperature synthesis, Microporous Mesoporous Mater. 31 (1-2) (1999) 141-150.
[23] Q.H. Li, B. Mihailova, D. Creaser, J. Sterte, The nucleation period for crystallization of colloidal TPA-silicalite-1 with varying silica source, Microporous Mesoporous Mater. 40 (1-3) (2000) 53-62.
[24] Q.H. Li, B. Mihailova, D. Creaser, J. Sterte, Aging effects on the nucleation and crystallization kinetics of colloidal TPA-silicalite-1, Microporous Mesoporous Mater. 43 (1) (2001) 51-59.
[25] Q.H. Li, D. Creaser, J. Sterte, An investigation of the nucleation/crystallization kinetics of nanosized colloidal faujasite zeolites, Chem. Mater. 14 (3) (2002) 1319-1324.
[26] M. Avrami, Kinetics of phase change. I General theory, The Journal of Chemical Physics, 7 (1939) 1103-1112.
[27] M. Avrami, Kinetics of phase change. II Transformation-time relations for random distribution of nuclei, The Journal of Chemical Physics, 8 (1940) 212-224.
[28] M. Avrami, Granulation, phase change, and microstructure Kinetics of phase change. III, The Journal of Chemical Physics, 9 (1941) 177-184.
[29] A.F. Gualtieri, Synthesis of sodium zeolites from a natural halloysite, Phys. Chem. Miner. 28 (10) (2001) 719-728.
[30] P.F. Corregidor, D.E. Acosta, H.A. Destefanis, Kinetic study of seed-assisted crystallization of ZSM-5 zeolite in an OSDA-free system using a natural aluminosilicate as starting source, Ind. Eng. Chem. Res. 57 (41) (2018) 13713-13720.
[31] A. Nakhaei Pour, A. Mohammadi, Effects of synthesis parameters on organic template-free preparation of zeolite Y, J. Inorg. Organomet. Polym. Mater. 31 (6) (2021) 2501-2510.
[32] J. Liu, J.Y. Zhang, H.Z. Zhang, F. Zhang, M.H. Zhu, N. Hu, X.S. Chen, H. Kita, Synthesis of hierarchical zeolite T nanocrystals with the assistance of zeolite seed solution, J. Solid State Chem. 285 (2020) 121228.
[33] R.M. Dewes, H.R. Mendoza, M.V.L. Pereira, C. Lutz, T. Van Gerven, Experimental and numerical investigation of the effect of ultrasound on the growth kinetics of zeolite A, Ultrason. Sonochem. 82 (2022) 105909.
[34] S.G. Fegan, B.M. Lowe, Effect of alkalinity on the crystallisation of silicalite-1 precursors, J. Chem. Soc., Faraday Trans. 1 82 (3) (1986) 785.
[35] M.L. Guzman Castillo, F. Di Renzo, F. Fajula, J. Bousquet, Crystallization kinetics of zeolite omega, the synthetic analog of mazzite, Microporous Mesoporous Mater. 90 (1-3) (2006) 221-228.
[36] J. Bronić, A. Palčić, B. Subotic, L. Itani, V. Valtchev, Influence of alkalinity of the starting system on size and morphology of the zeolite A crystals, Mater. Chem. Phys. 132 (2-3) (2012) 973-976.
[37] D.D. Guo, B.J. Shen, Y.C. Qin, J.X. Sun, Q.X. Guo, S.Y. Ren, X.H. Gao, X.M. Pang, B.J. Wang, H.J. Zhao, H.H. Liu, USY zeolites with tunable mesoporosity designed by controlling framework Fe content and their catalytic cracking properties, Microporous Mesoporous Mater. 211 (2015) 192-199.
[38] F. Delprato, L. Delmotte, J.L. Guth, L. Huve, Synthesis of new silica-rich cubic and hexagonal faujasites using crown-etherbased supramolecules as templates, Zeolites 10 (6) (1990) 546-552.
[39] P. Lv, L.J. Yan, Y. Liu, M.J. Wang, W.R. Bao, F. Li, Catalytic conversion of coal pyrolysis vapors to light aromatics over hierarchical Y-type zeolites, J. Energy Inst. 93 (4) (2020) 1354-1363.
[40] B. Meng, S.Y. Ren, Z. Li, S.F. Nie, X.Y. Zhang, W.Y. Song, Q.X. Guo, B.J. Shen, A facile organic-free synthesis of high silica zeolite Y with small crystal in the presence of Co²⁺, Microporous Mesoporous Mater. 323 (2021) 111248.

Synthesis of NaY zeolite from a submolten depolymerized perlite: Alkalinity effect and crystallization kinetics

Synthesis of NaY zeolite from a submolten depolymerized perlite: Alkalinity effect and crystallization kinetics

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