Highly-efficient separation of pyromellitic acid and trimellitic acid mixtures via forming deep eutectic solvents: Experiment and calculation

doi:10.1016/j.cjche.2024.09.012

Chinese Journal of Chemical Engineering ›› 2024, Vol. 76 ›› Issue (12): 42-48.DOI: 10.1016/j.cjche.2024.09.012

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Highly-efficient separation of pyromellitic acid and trimellitic acid mixtures via forming deep eutectic solvents: Experiment and calculation

Wanxiang Zhang¹, Lixia Ji¹, Yucui Hou², Shuhang Ren¹, Weize Wu¹

1. State Key Laboratory of Chemical Resource Engineering, Beijing University of Chemical Technology, Beijing 100029, China;
2. Department of Chemistry and Materials, Taiyuan Normal University, Shanxi 030619, China

Received:2024-06-10 Revised:2024-09-19 Accepted:2024-09-23 Online:2024-10-16 Published:2024-12-28
Contact: Shuhang Ren,E-mail:rensh@mail.buct.edu.cn;Weize Wu,E-mail:wzwu@mail.buct.edu.cn
Supported by:
The authors thank Prof. Zhenyu Liu and Qingya Liu for their helpful discussion and suggestions and the long-term subsidy mechanism from the Ministry of Finance and the Ministry of Education of PRC (BUCT). The project is financially supported by the National Natural Science Foundation of China (21676019 and 21776199).

Highly-efficient separation of pyromellitic acid and trimellitic acid mixtures via forming deep eutectic solvents: Experiment and calculation

Wanxiang Zhang¹, Lixia Ji¹, Yucui Hou², Shuhang Ren¹, Weize Wu¹

1. State Key Laboratory of Chemical Resource Engineering, Beijing University of Chemical Technology, Beijing 100029, China;
2. Department of Chemistry and Materials, Taiyuan Normal University, Shanxi 030619, China

通讯作者: Shuhang Ren,E-mail:rensh@mail.buct.edu.cn;Weize Wu,E-mail:wzwu@mail.buct.edu.cn
基金资助:
The authors thank Prof. Zhenyu Liu and Qingya Liu for their helpful discussion and suggestions and the long-term subsidy mechanism from the Ministry of Finance and the Ministry of Education of PRC (BUCT). The project is financially supported by the National Natural Science Foundation of China (21676019 and 21776199).

Abstract

Abstract: Pyromellitic acid (PMA) and trimellitic acid (TMA) are significant chemical raw materials and intermediates. They simultaneously exist in the industry processes of synthesis and are difficult to be separated. In this work, several kinds of biodegradable compounds were chosen as hydrogen bond acceptors (HBAs) to separate PMA and TMA mixtures from acetone solutions via forming deep eutectic solvent (DES). It has been found that all these compounds can separate PMA and TMA mixtures to obtain pure PMA or TMA. However, the interaction between HBAs and PMA or TMA is quite different. Choline chloride cannot extract TMA but can form a DES with PMA in acetone. Hexamethylenetetramine (HA) and L-carnitine (L-car) can form DESs with both PMA and TMA in acetone solution. But when L-car or HA is added, the extraction rate of PMA is larger than that of TMA until the extraction rate of PMA reach 100%, and pure TMA is left in the acetone solution. The selective separation mechanism was explored by infrared spectroscopy combined with quantum chemistry calculation, and the strength and site of the interaction between extractants with PMA and TMA were calculated.

Key words: Separation, Pyromellitic acid, Trimellitic acid, Deep eutectic solvent, Quantum chemistry calculation

摘要： Pyromellitic acid (PMA) and trimellitic acid (TMA) are significant chemical raw materials and intermediates. They simultaneously exist in the industry processes of synthesis and are difficult to be separated. In this work, several kinds of biodegradable compounds were chosen as hydrogen bond acceptors (HBAs) to separate PMA and TMA mixtures from acetone solutions via forming deep eutectic solvent (DES). It has been found that all these compounds can separate PMA and TMA mixtures to obtain pure PMA or TMA. However, the interaction between HBAs and PMA or TMA is quite different. Choline chloride cannot extract TMA but can form a DES with PMA in acetone. Hexamethylenetetramine (HA) and L-carnitine (L-car) can form DESs with both PMA and TMA in acetone solution. But when L-car or HA is added, the extraction rate of PMA is larger than that of TMA until the extraction rate of PMA reach 100%, and pure TMA is left in the acetone solution. The selective separation mechanism was explored by infrared spectroscopy combined with quantum chemistry calculation, and the strength and site of the interaction between extractants with PMA and TMA were calculated.

关键词: Separation, Pyromellitic acid, Trimellitic acid, Deep eutectic solvent, Quantum chemistry calculation

Wanxiang Zhang, Lixia Ji, Yucui Hou, Shuhang Ren, Weize Wu. Highly-efficient separation of pyromellitic acid and trimellitic acid mixtures via forming deep eutectic solvents: Experiment and calculation[J]. Chinese Journal of Chemical Engineering, 2024, 76(12): 42-48.

References

[1] F. Rosowski, S. Altwasser, C.K. Dobner, S. Storck, J. Zuhlke, H. Hibst, New silver- and vanadium-containing multimetal oxides for oxidation of aromatic hydrocarbons, Catal. Today 157 (1-4) (2010) 339-344.
[2] K. Du, Y. Li, L. Lin, H. Wu, Preparation of pyromellitic anhydride and terephthalic acid from anthracite, Solid Fuel Chem. 50 (2016) 268-276.
[3] D. Zhang, Q. Xu, Solubility of 1,3,5-benzenetricarboxylic acid in different solvents, J. Chem. Eng. Data 61 (2) (2016) 1003-1006.
[4] A.P. Abbott, G. Capper, D.L. Davies, R.K. Rasheed, V. Tambyrajah, Novel solvent properties of choline chloride/urea mixtures, Chem. Commun. (1) (2003) 70-71.
[5] W.X. Zhang, Z.G. Lei, Y. Wang, J. Wei, S.H. Ren, Y.C. Hou, W.Z. Wu, Molecular mechanism and process of efficient separation of benzene and cyclohexane using a low-cost deep eutectic solvent, Chem. Eng. Sci. 279 (2023) 118963.
[6] N. Kumar, T. Banerjee, Molecular mechanism and solubility performance evaluation for separation of benzothiophene and model diesel compounds through deep eutectic solvents as extractants, Ind. Eng. Chem. Res. 61 (3) (2022) 1464-1474.
[7] P. Makos, G. Boczkaj, Deep eutectic solvents based highly efficient extractive desulfurization of fuels-Eco-friendly approach, J. Mol. Liq. 296 (2019) 111916.
[8] L. Yi, X.Q. Wu, L. Guo, J.L. Chen, M. Gauthier, W.Y. Li, Applications of ionic liquids and deep eutectic solvents for the extraction of phenolic compounds from coal-based crude oils, Sep. Purif. Technol. 337 (2024) 126383.
[9] K. Pang, Y.C. Hou, W.Z. Wu, W.J. Guo, W. Peng, K.N. Marsh, Efficient separation of phenols from oils via forming deep eutectic solvents, Green Chem. 14 (9) (2012) 2398-2401.
[10] C.F. Yao, Y.C. Hou, S.H. Ren, W.Z. Wu, Y.A. Ji, H. Liu, Sulfonate based zwitterions: A new class of extractants for separating phenols from oils with high efficiency via forming deep eutectic solvents, Fuel Process. Technol. 178 (2018) 206-212.
[11] C.F. Yao, Y.C. Hou, S.H. Ren, W.Z. Wu, K. Zhang, Y.A. Ji, H. Liu, Efficient separation of phenol from model oils using environmentally benign quaternary ammonium-based zwitterions via forming deep eutectic solvents, Chem. Eng. J. 326 (2017) 620-626.
[12] W.J. Guo, Y.C. Hou, W.Z. Wu, S.H. Ren, S.D. Tian, K.N. Marsh, Separation of phenol from model oils with quaternary ammonium salts via forming deep eutectic solvents, Green Chem. 15 (1) (2013) 226-229.
[13] Y. Zhang, Z.Y. Li, H.Y. Wang, X.P. Xuan, J.J. Wang, Efficient separation of phenolic compounds from model oil by the formation of choline derivative-based deep eutectic solvents, Sep. Purif. Technol. 163 (2016) 310-318.
[14] Y.C. Hou, J. Li, S.H. Ren, M.G. Niu, W.Z. Wu, Separation of the isomers of benzene poly(carboxylic acid)s by quaternary ammonium salt via formation of deep eutectic solvents, J. Phys. Chem. B 118 (47) (2014) 13646-13650.
[15] W.H. Wang, Y.C. Hou, W.Z. Wu, M.G. Niu, T. Wu, High-temperature alkali-oxygen oxidation of lignite to produce benzene polycarboxylic acids, Ind. Eng. Chem. Res. 52 (2) (2013) 680-685.
[16] F. Yang, Y.C. Hou, W.Z. Wu, Z.Y. Liu, The generation of benzene carboxylic acids from lignite and the change in structural characteristics of the lignite during oxidation, Fuel 203 (2017) 214-221.
[17] T. Niemann, A. Strate, R. Ludwig, H.J. Zeng, F.S. Menges, M.A. Johnson, Spectroscopic evidence for an attractive cation-cation interaction in hydroxy-functionalized ionic liquids: A hydrogen-bonded chain-like trimer, Angew. Chem. Int. Ed. 57 (47) (2018) 15364-15368.
[18] G.Q. Yu, R.N. Xu, B. Wu, N. Liu, B.H. Chen, C.N. Dai, Y. Kuang, Z.G. Lei, Molecular thermodynamic and dynamic insights into gas dehydration with imidazolium-based ionic liquids, Chem. Eng. J. 416 (2021) 129168.
[19] Z.J. Shang, P. Xu, G.X. Li, W.X. Zhang, Z.R. Chen, Q.H. Liu, Ionic-liquid-assisted capture of volatile low-carbon alcohols in printing plant exhaust gas, ACS Sustain. Chem. Eng. 12 (14) (2024) 5661-5674.
[20] T. Lu, Molclus Program, Version 1.12. http://www.keinsci.com/research/molclus.html (2023-8-23).
[21] T. Lu, Q.X. Chen, Interaction region indicator: A simple real space function clearly revealing both chemical bonds and weak interactions, Chemistry-Methods 1 (5) (2021) 231-239.
[22] J.S. Murray, P. Politzer, The electrostatic potential: An overview, Wires Comput. Mol. Sci. 1 (2) (2011) 153-163.
[23] Q. Liu, X.L. Zhang, Z.W. Qi, Extractive mechanism and process design of hydroxyl-functionalized pyridinium-based ionic liquids for separating m-cresol and cumene, ACS Sustain. Chem. Eng. 12 (1) (2024) 310-324.
[24] D.R. Lide, CRC Handbook of Chemistry and Physics (86th ed.), CRC Press, Boca Raton, 2005.
[25] J.G. Qi, Y.J. Qu, M.J. Zhou, Z.H. Su, X.Y. Zhang, R.R. Wei, K. Xue, Z.Y. Zhu, F.Q. Meng, Y.L. Wang, Phase behavior and molecular insights on the separation of dimethyl carbonate and methanol azeotrope by extractive distillation using deep eutectic solvents, Sep. Purif. Technol. 305 (2023) 122489.
[26] C.M. Gui, G.X. Li, M.H. Song, Z.G. Lei, Absorption of dichloromethane in deep eutectic solvents: Experimental and computational thermodynamics, Sep. Purif. Technol. 311 (2023) 123281.
[27] Y.S. Dai, X.J. Chu, Y.Y. Jiao, Y.N. Li, F.L. Shan, S. Zhao, G.X. Li, Z.G. Lei, P.Z. Cui, Z.Y. Zhu, Y.L. Wang, Molecular insights into azeotrope separation in the methyl tert-butyl ether production process using ChCl-based deep eutectic solvents, Chem. Eng. Sci. 264 (2022) 118179.

Highly-efficient separation of pyromellitic acid and trimellitic acid mixtures via forming deep eutectic solvents: Experiment and calculation

Highly-efficient separation of pyromellitic acid and trimellitic acid mixtures via forming deep eutectic solvents: Experiment and calculation

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