Synergy between heterogeneous catalysis and homogeneous radical reactions for pharmaceutical waste destruction: Perspective

doi:10.1016/S1872-2067(23)64599-1

Abstract

Abstract:

Enormous quantities of pharmaceuticals are consumed by humans leading to a growing and continuous release of harmful components into the environment. Existing conventional water treatment plants are designed mainly for eliminating biodegradable organics and nutrients and cannot degrade pharmaceuticals and personal care products efficiently enough due to their chemical stability. Advanced oxidation processes using radicals generated from ozone can be efficiently combined with heterogeneous catalysis for treatment of wastewater containing pharmaceuticals and personal care products. From the technology viewpoint, elimination of pharmaceuticals from water by heterogeneously catalyzed ozonation should done in a continuous fixed bed reactor. The structured catalysts can be prepared by additive manufacturing using 3D-direct printing of supports/catalysts allowing a high degree of freedom in both the composition and design of the final catalytic material for a fixed bed heterogeneous-homogeneous reaction. Structured materials can exhibit non-periodic structure, such as for example semi-ordered structures, inspired by nature. For periodic and semi-periodic structures, heat and mass transfer should be investigated using computational fluid dynamics and flow imaging methods, guiding further design of novel architectures and subsequently allowing in combination with the materials development efficient control of activity and selectivity. The innovative catalytic reactor engineering should include experimental and numerical investigation of the stage wise injection of the oxidation agent, variation of the reactor cross-section size, changing the distance between the catalyst beds and introduction of the recycle loops.

Key words: Reaction engineering, Ozonation, Zeolite, Pharmaceuticals, Additive manufacturing

Dmitry Yu. Murzin. Synergy between heterogeneous catalysis and homogeneous radical reactions for pharmaceutical waste destruction: Perspective[J]. Chinese Journal of Catalysis, 2024, 58: 7-14.

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URL: https://www.cjcatal.com/EN/10.1016/S1872-2067(23)64599-1

https://www.cjcatal.com/EN/Y2024/V58/I3/7

Figures/Tables 5

Fig. 1. Structures of some persistent pharmaceuticals.

Fig. 2. Overview of ozonation reaction with micropollutants, R presents reaction product and M presents a micropollutant [15].

Fig. 3. Objects obtained by 3D printing using digital lighting processing: (a) reactor internals, (b) ceramic structures. Courtesy L. Mastroianni (?bo Akademi University).

Fig. 4. Visualizaton of the bed sequence and several ozone injection points.

Fig. 5. Engineering of homogeneous radical reactions and heterogeneous catalytic reactions in hydrocarbons selective catalytic reduction of NOx by zoning: (a) pilot testing of an exhaust pipe with 5 catalyst bricks; (b) [24] and (c) [39] lab scale experiments.

References

[1]	D. White, D. J. Lapworth, W. Civil, P. Williams, Environ. Pollut., 2019, 249, 257-266.
[2]	H. Q. Liu, J. C. W. Lam, W. W. Li, H. Q. Yu, P. K. S. Lam, Sci. Total Environ., 2017, 586, 1162-1169.
[3]	M. S. U. Rehman, N. Rashid, M. Ashfaq, A. Saif, N. Ahmad, J. I. Han, Chemosphere, 2015, 138, 1045-1055.
[4]	J. Wang, S. Wang, J. Environ. Manage., 2016, 182, 620-640.
[5]	M. Tokumura, A. Sugawara, M. Raknuzzaman, M. Habibullah-Al-Mamun, S. Masunaga, Chemosphere, 2016, 159, 317-325.
[6]	A. J. Ebele, M. A. Abdallah, S. Harrad, Emerg. Contam., 2017, 3, 1-16.
[7]	S. Saeid, P. Tolvanen, N. Kumar, K. Eränen, J. Peltonen, M. Peurla, J.-P. Mikkola, A. Franz, T. Salmi, Appl. Catal. B, 2018, 230, 77-90.
[8]	J. Martin, D. Camacho-Munoz, J. L. Santos, I. Aparicio, E. Alonso, J. Hazard. Mater., 2021, 239- 240, 40-47.
[9]	A. Meierjohann, J. M. Brozinski, L. Kronberg, Environ. Sci. Process. Impacts, 2016, 18, 342-349.
[10]	E. Issaka, J. N.-O. Amu-Darko, S. Yakubu, F. O. Fapohunda, N. Ali, M. Bilal, Chemosphere, 2022, 289, 133208.
[11]	D. Kanakaraju, B. D. Glass, M. Oelgem, J. Environ. Manage., 2018, 219, 189-207.
[12]	J. Gomes, R. Costa, R. M. Quinta-Ferreira, R. C. Martins, Sci. Total Environ., 2017, 586, 265-283.
[13]	K. Gonzalez-Labrada, R. Richard, C. Andriantsiferana, H. Valdes, U. J. Jauregui-Haza, M.-H. Manero, Environ. Sci. Pollut. Res., 2020, 27, 1246-1255.
[14]	D. Schmiemann, L. Hohenschon, I. Bartels, A. Hermsen, F. Bachmann, A. Cordes, M. Jäger, J. S. Gutmann, K. Hoffman-Jacobsen, Environ. Sci. Pollut. Res., 2023, 30, 53128-53319.
[15]	J. Wang, Z. Bai, Chem. Eng. J., 2017, 312, 79-98.
[16]	H. Khan, K. Gul, B. Ara, A. Khan, N. Ali, N. Ali, M. Bilal, J. Environ. Chem. Eng., 2020, 8, 103927
[17]	H. Farzaneh, K. Loganathan, J. Saththasivaram, G. McKay, Sci. Total Environ., 2021, 765, 142704.
[18]	M. Kråkström, S. Saeid, P. Tolvanen, T. Salmi, L. Kronberg, P. Eklund, Chemosphere, 2020, 247, 125853.
[19]	S. Saeid, M. Kråkström, P. Tolvanen, N. Kumar, K. Eränen, J. P. Mikkola, L. Kronberg, P. Eklund, M. Peurla, A. Aho, T. Salmi, Catalysts, 2020, 10, 90.
[20]	S. Saeid, Destruction of selected pharmaceuticals by ozonation and heterogeneous catalysis, PhD thesis, Åbo Akademi University, 2020.
[21]	S. Inagaki, K Thomas, V. Ruaux, G. Clet, T. Wakihara, S. Shinoda, S. Okamura, Y. Kubota, V. Valtchev, ACS Catal., 2014, 4, 2333-2341.
[22]	Y. He, Y. Cai, S. Fan, T. Meng, Y. Zhang, X. Li, Y. Zhang,, J. Hazard. Mater., 2022, 438, 129503.
[23]	S. Lim, J. L. Shi, U. von Gunten, D. L. McCurry, Water Res., 2022, 213, 118053.
[24]	K. Arve, F. Klingstedt, K. Eränen, L.-E. Lindfors, D. Yu. Murzin, Catal. Lett., 2005, 105, 133-138.
[25]	J. Wang, Y. Xie, G. Yu, L. Yin, J. Xiao, Y. Wang, W. Lv, Z. Sun, J.-H. Kim, H. Cao, Environ. Sci. Technol., 2022, 56, 17753-17762.
[26]	S. Zhang, G. Yu, J. Chen, Q. Zhao, X. Zhang, B. Wang, J. Huang, S. Deng, Y. Wang, Environ. Poll., 2017, 220, 971-980.
[27]	S. Yu. Devyatkov, A. A. Zinnurova, A. Aho, D. Kronlund, J. Peltonen, N. V. Kuzichkin, N. V. Lisitsyn, D. Yu. Murzin, Ind. Eng. Chem. Res., 2016, 55, 6595-6606.
[28]	Z. Vajglová, N. Kumar, M. Peurla, J. Peltonen, D. Yu. Murzin, Catal. Sci. Technol., 2018, 8, 6150-6162.
[29]	Z. Vajglova, N. Kumar, M. Peurla, L. Hupa, K. Semikin, D. Sladkovskiy, D. Yu. Murzin, Ind. Eng. Chem. Res., 2019, 58, 10875-10885.
[30]	I. Simakova, Z. Vajglová, P. Mäki-Arvela, K. Eränen, L. Hupa, M. Peurla, E. Mäkilä, J. Wärnå, D. Yu. Murzin, Org. Proc. Res. Dev., 2022, 26, 387-403.
[31]	I. Simakova, Z. Vajglová, M. Martinez-Klimov, P. Mäki-Arvela, K. Eränen, M. Peurla, D. Yu. Murzin, Org. Proc. Res. Dev., 2023, 27, 295-310.
[32]	A. Najarnezhadmashhadi, K. Eränen, S. Engblom, A. Aho, D.Yu. Murzin,. T. Salmi, Ind. Eng. Chem. Res., 2020, 59, 13450-13459.
[33]	A. Najarnezhadmashhadi, J. Wärnå, K. Eränen, H. Trajano, D. Murzin, T. Salmi, Chem. Eng. Sci., 2021, 233, 116385.
[34]	V. Shumilov, A. Kirilin, A. Tokarev, S. Boden, M. Schubert, U. Hampel, L. Hupa, T. Salmi, D. Yu. Murzin, Catal. Today, 2022, 383, 64-73.
[35]	H. Wang, P. Wang, Q. Wang, R. Zhang, L. Zhang, Ind. Eng. Chem. Res., 2021, 60, 13107-13114.
[36]	https://catalysts.basf.com/news/basf-introduces-x3dtm-a-revolutionary-catalyst-shaping-technology-for-optimized-catalyst-performance.
[37]	T. Chartier, A. Badev, Y. Abouliatim, P. Lebaudy, L. Lecamp, J. Eur. Ceram. Soc., 2012, 32, 1625-1634.
[38]	J. A. A. Hoorn, G.F. Versteeg, Chem. Eng. Sci., 2006, 61, 5137-5148.
[39]	K. Arve, E. A. Popov, M. Rönnholm, F. Klingstedt, J. Eloranta, K. Eränen, D. Yu. Murzin, Chem. Eng. Sci., 2004, 59, 5277-5282.
[40]	https://turunseudunpuhdistamo.fi/in-english.
[41]	S. Svebrant, R. Spörndly, R. H. Lindberg, T. Olsen Sköldstam, J. Larsson, P. Öhagen, H. Söderström Lindström, J. D. Järhult, Antibiotics-Basel., 2021, 10, 684.