Versatile catalytic membranes anchored with metal-nitrogen based metal oxides for ultrafast Fenton-like oxidation

Versatile catalytic membranes anchored with metal-nitrogen based metal oxides for ultrafast Fenton-like oxidation

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Qingbai Tian^a, BingLiang Yu^a, Zhihao Li^b^,^*, Wei Hong^c^,^*, Qian Li^a, Xing Xu^a^,^*

Chinese Chemical Letters | 2025, 36(6) : 110322

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Chinese Chemical Letters | 2025, 36(6): 110322

• Communication •

Versatile catalytic membranes anchored with metal-nitrogen based metal oxides for ultrafast Fenton-like oxidation

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Qingbai Tian^a, BingLiang Yu^a, Zhihao Li^b^,^*, Wei Hong^c^,^*, Qian Li^a, Xing Xu^a^,^*

Affiliations

^a Shandong Key Laboratory of Water Pollution Control and Resource Reuse, School of Environmental Science and Engineering, Shandong University, Qingdao 266237, China

^b Henan water Conservancy Survey design Research Co., Ltd., Zhengzhou 450000, China

^c Shandong Resources and Environment Construction Group Co., Ltd., Ji’nan 250100, China

Published: 2025-06-15 doi: 10.1016/j.cclet.2024.110322

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Abstract

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Although the powder Fenton-like catalysts have exhibited high catalytic performances towards pollutant degradation, they cannot be directly used for Fenton-like industrialization considering the problems of loss and recovery. Therefore, the membrane fixation of catalyst is an important step to realize the actual application of Fenton-like catalysts. In this work, an efficient catalyst was developed with Co-N_x configuration facilely reconstructed on the surface of Co₃O₄ (Co-N_x/Co₃O₄), which exhibited superior catalytic activity. We further fixed the highly efficient Co-N_x/Co₃O₄ onto three kinds of organic membranes and one kind of inorganic ceramic membrane installing with the residual PMS treatment device to investigate its catalytic stability and sustainability. Results indicated that the inorganic ceramic membrane (CM) can achieve high water flux of 710 L m^-2 h^-1, and the similar water flux can be achieved by Co-N_x/Co₃O₄/CM even without the pressure extraction. We also employed the Co-N_x/Co₃O₄/CM system to the wastewater secondary effluent, and the pollutant in complicated secondary effluent could be highly removed by the Co-Nx/Co₃O₄/CM system. This paper provides a new point of view for the application of metal-based catalysts with M-N_x coordination in catalytic reaction device.

Key words

Peroxymonosulfate / Catalytic membranes / Metal oxides / Fenton-like reaction / Ceramic membrane

Cite this Article

Qingbai Tian, BingLiang Yu, Zhihao Li, Wei Hong, Qian Li, Xing Xu. Versatile catalytic membranes anchored with metal-nitrogen based metal oxides for ultrafast Fenton-like oxidation[J]. Chinese Chemical Letters, 2025 , 36 (6) : 110322 - . DOI: 10.1016/j.cclet.2024.110322

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All kinds of emerging pollutants in water come from various supplies in production and life, such as drugs, skin care products, and various additives [1-4]. These emerging pollutants have a variety of potential effects on people and the environment. However, the traditional treatment technology is difficult to achieve efficient removal of new pollutants, because the emerging pollutants have the characteristics of low concentration and hard to degradation [5-8]. In recent decades, advanced oxidation technologies based on various oxidants (such as perhydrogen peroxide, persulfate, ozone, peracetic acid) have received increasing attentions, because various active substances produced after the activation of these oxidants can efficiently remove various emerging pollutants [9-12]. In recent decades, the advanced oxidation process based on peroxo sulfate (PMS-AOPs) has received more and more attention in the degradation of refractory organic pollutants in water due to its ability to produce a variety of reactive oxygen species (ROS) and strong oxidation capacity. At present, the use of heterogeneous catalysts (metal oxides, carbon-based catalysts or metal carbon-based composite catalysts) to achieve high efficiency activation of PMS is widely studied, but in practical applications, it still faces challenges such as catalytic stability and recovery of powder catalysts [13-15].

Heterogeneous Fenton reaction treats various organic pollutants in water by generating strong oxidizing free radicals and non-free radicals [16,17]. For traditional fully mixed laboratory systems (e.g., beakers, conical bottles), particles dispersed in water face the following problems: (1) Low mass transfer efficiency leads to residual PMS of the system and reduces the oxidation capacity of heterogeneous Fenton system; (2) ROS generated cannot contact the target pollutants quickly, resulting in self-quenching of free radicals or ineffective oxidation reactions (such as the reaction with water molecules) [18-21]. In order to achieve an efficient heterogeneous Fenton system, it is still necessary to improve the reactor operation modules. Many scholars have proposed the concept of membrane confined effect in collaboration with radical/nonradical surface reactions to strengthen the mass transfer process of the system, and developed an advanced oxidized water purification system with high efficiency, high selectivity and high reaction metrology efficiency, and carried out systematic research on reaction unit design and application strengthening [22-24]. According to different catalyst types (carbon, metal oxides, and metal/carbon hybrids), the membrane catalytic reaction unit with stable catalyst load and high reaction activity was constructed by introducing the strategies of "self-support" and "polymerization-coating" [21,25,26]. Related studies have solved the problem of low efficiency of lab-scale advanced oxidation technology, and extended the engineering application potential of advanced oxidation water purification technology dominated by free radicals/nonradical pathways [1-3,27-31]. However, there are few systematic studies on multiple catalytic membranes to investigate the water fluxes and degradation performances of different membranes. This is also the focus of this study.

In this work, a cobalt-nitrogen doped cobalt-trioxide catalyst (Co-N_x/Co₃O₄) was designed and fabricated by the simple one-step calcination. The structure and composition characteristics of Co-N_x/Co₃O₄ catalyst was analyzed. The catalyst was loaded on the surface of four kinds of inorganic and organic membrane materials (proton exchange membrane (PEM), polytetrafluoroethylene (PTFE), and regenerated cellulose (RC), ceramic membrane (CM)) to investigate the continuous degradation performances of antibiotics in the real environmental conditions.

The Co-N_x coordinated Co₃O₄ (Co-N_x/Co₃O₄) was prepared under ammonia atmosphere. The scanning electron microscopy (SEM) images of Co-N_x/Co₃O₄ displayed that the as-prepared catalyst was formed via stacking the ultra-thin nanosheets (Figs. 1a and b). The distribution of element obtained from the SEM results indicated that the nitrogen derived from ammonia has been introduced into the Co₃O₄ (Fig. 1c and Fig. S1 in Supporting information). The atomic force microscopy (AFM) result further confirmed the structure of Co-N_x/Co₃O₄ in the form of nanosheet (Fig. S2 in Supporting information). Transmission electron microscope (TEM) of the Co-N_x/Co₃O₄ showed that the size of Co-N_x/Co₃O₄ was in the range 50–100 nm (Fig. 1d). In addition, the specific crystal lattices of Co₃O₄ can also be observed in the Co-N_x/Co₃O₄ nanosheet based on the TEM image. For example, planes of Co₃O₄ (440) and (311) showed the specific crystal lattices at 0.143 and 0.244 nm [18,32], respectively (Fig. 1d and Fig. S3 in Supporting information).

The degradation performances of Co-N_x/Co₃O₄ towards different pollutants were shown in Fig. S4 (Supporting information). Results indicated that the Co-N_x/Co₃O₄ could 100% degrade the paracetamol (PCM) and bisphenol-A (BPA) via PMS activation, which exhibited the ultrafast degradation activity of Co-N_x/Co₃O₄. The electron paramagnetic resonance (EPR) detection indicated that the radical species could be generated and contribute to degradation reaction (Fig. S5 in Supporting information). In addition, open circuit potential of Co-N_x/Co₃O₄ confirmed that there are Co-N_x/Co₃O₄+PMS* in the catalytic system [20,33-38], and the addition of pollutants would result in a sharp decrease in the potential of Co-N_x/Co₃O₄ electrode (Fig. S6 in Supporting information). In contrast, there was no decrease in the potential of Co₃O₄ electrode. It was known that electron-transfer process (ETP) can be triggered via the metal-nitrogen coordinated structures [36]. As a result, two major oxidation pathways (radical oxidation, and ETP oxidation) towards different pollutants can be triggered in the Co-N_x/Co₃O₄/PMS system, which guaranteed the high-effective degradation activity of Co-N_x/Co₃O₄.

Four kinds of membrane materials, including the organic materials (PEM, PTFE, and RC) and inorganic CM were selected for depositing the resulting catalyst to form the catalytic membranes (Co-N_x/Co₃O₄/PEM, Co-N_x/Co₃O₄/PTFE, Co-N_x/Co₃O₄/RC, and Co-N_x/Co₃O₄/CM). Their fabrication procedures were shown in Figs. 1e and f, which showed two different preparation routines. The Co-N_x/Co₃O₄/PEM, Co-N_x/Co₃O₄/PTFE, and Co-N_x/Co₃O₄/RC membranes were fabricated via vacuum filtration of the as-prepared Co-N_x/Co₃O₄ catalyst onto the 7 cm-shaped PEM, PTFE, and RC membranes. Their actual images were given in Fig. S7 (Supporting information). In contrast, the fabrication of Co-N_x/Co₃O₄/CM was based on the airbrush spraying routine via spraying the Co-N_x/Co₃O₄ inks onto the CMs [36,39], as shown in Fig. S8 (Supporting information).

The SEM cross section images of the four catalytic membranes were shown in Fig. 2 and Fig. S9 (Supporting information). The Co-N_x/Co₃O₄/PEM displayed two hierarchies with the thickness of deposited Co-N_x/Co₃O₄ layer approximately 60 µm (Fig. 2a). Similarly, the steady Co-N_x/Co₃O₄ layers can be deposited on the PTFE, RC, and CM with the similar thicknesses of 60, 40, and 50 µm, respectively (Figs. 2b and c). As a result, all the four catalytic membranes (including Co-N_x/Co₃O₄/PEM, Co-N_x/Co₃O₄/PTFE, Co-N_x/Co₃O₄/RC, and Co-N_x/Co₃O₄/CM) could provide sufficient reactive sites for oxidizing the pollutants via continuous influent flows. The hydrophilicity properties of various catalytic membranes were determined by contact angle experiments [39]. The contact angle results exhibited that depositing the Co-N_x/Co₃O₄ onto the organic membranes (PEM, PTFE, and RC) required 0.32–0.74 s for water assimilation (Figs. 2d-f). In contrast, the complete water assimilation of Co-N_x/Co₃O₄/CMs could be achieved within 0.03 s (Fig. S9b). In addition, the Co-N_x/Co₃O₄ deposited membranes exhibited similar or even higher hydrophilicity properties as compared with those of bare membranes; this might be attributed to the high populations of oxygen-based groups on these Co-N_x/Co₃O₄ deposited membranes, which would accelerate the formation of hydrogen bonds with water molecules and facilitate the water assimilation on the membrane surfaces [36,39].

In addition, the coating of Co-N_x/Co₃O₄ onto different membranes showed significantly different flux changes. As shown in Figs. 3a and b, the water flux of original CR was very low (< 30 L m^-2 h^-1), and the Co-N_x/Co₃O₄/CR was even lower than 10 L m^-2 h^-1 (pressure extraction also cannot improve the water flux of Co-N_x/Co₃O₄/CR). As for the original PTFE and Co-N_x/Co₃O₄/PTFE, very low water fluxes were obtained without the pressure extraction (Figs. 3c and d), while the water flux of Co-N_x/Co₃O₄/PTFE can be significantly improved to 820 L m^-2 h^-1 at 0.4 MPa of pressure extraction. The Co-N_x/Co₃O₄/PES could achieve the similar water flux as compared with that of original PES at 0.02 MPa of pressure extraction (Figs. 3e and f). Basically, a certain pressure extraction was required for Co-N_x/Co₃O₄ deposited organic membranes (Co-N_x/Co₃O₄/CR, Co-N_x/Co₃O₄/PTFE, and Co-N_x/Co₃O₄/RC). In contrast, the inorganic CM can achieve high water flux of 710 L m^-2 h^-1, and the similar water flux can be achieved by Co-N_x/Co₃O₄/CM even without the pressure extraction (Figs. 3g and h). This result indicated that the inorganic CM can be more suitable for depositing the Co-N_x/Co₃O₄ for continuous Fenton-like reactions.

The Co-N_x/Co₃O₄/CM was then used for the continuous catalytic oxidation of various pollutants in actual Fenton-like system, as shown in Fig. 4a. A residual PMS consumption device (inner diameter of 8 cm and length of 30 cm) filled with Fe₃O₄ was also equipped. The Fe₃O₄ filled device could effectively consume the residual PMS in the wastewater secondary effluent, and no PMS can be detected in the effluent after the treatment of the Co-N_x/Co₃O₄/CM system (Fig. 4b). The Co-N_x/Co₃O₄/CM system showed that > 98.8% of a series of pollutants (e.g., PCM, BPA, TC, CP) could be stably removed with the continuous flow (20 L) into the catalytic system (Fig. S10 in Supporting information). We also employed the Co-N_x/Co₃O₄/CM system to the wastewater secondary effluent (Zibo Lvhuan wastewater treating plant), and the pollutant in complicated secondary effluent could be highly removed by the Co-N_x/Co₃O₄/CM system (Fig. 4c). These results indicated that the Co-N_x/Co₃O₄/CM could efficiently degrade the pollutants in complex environmental conditions, which exhibited promising application prospectives [21].

The SEM cross section image of used Co-N_x/Co₃O₄/CM after actual Fenton-like reaction was determined, which showed that the thickness of the Co-N_x/Co₃O₄ was almost the same as that in original Co-N_x/Co₃O₄/CM (Fig. 5a). This result exhibited the high stability of the Co-N_x/Co₃O₄/CM system. Basically, the Co-N_x/Co₃O₄/CM system could trigger two major oxidation pathways (radical oxidation, and ETP oxidation) towards different pollutants as obtained from the EPR and GOS systems [40], which guaranteed the high effective and stable degradation activity in the Co-N_x/Co₃O₄/CM system (Fig. 5b). DFT calculation exhibited multiple adsorption models for PMS by Co₃O₄ and Co-N_x/Co₃O₄ (Fig. 5c). Results also confirmed that the Co-N_x/Co₃O₄ could exhibit the optimal gibbs free energy (−5.40 eV) as well as the charge of PMS (−0.311), which would facilitate the multiple oxidation pathways in the Co-N_x/Co₃O₄/CM system via activating PMS [40,41], as shown in Fig. 5c.

In summary, developing the eco-friendly, and efficient catalysts for decontaminating the antibiotic wastewaters has become the focus of research in recent years. In this work, Co-N_x coordinated Co₃O₄ (Co-N_x/Co₃O₄) was prepared under ammonia atmosphere, which was formed via stacking the ultra-thin nanosheets. The Co-N_x/Co₃O₄ could 100% degrade the paracetamol (PCM) and bisphenol-A (BPA) via PMS activation, which exhibited the ultrafast degradation activity of Co-N_x/Co₃O₄. Two major oxidation pathways (radical oxidation, and ETP oxidation) towards different pollutants can be triggered in the Co-N_x/Co₃O₄/PMS system, which guaranteed the high-effective degradation activity of Co-N_x/Co₃O₄. The Co-N_x/Co₃O₄ was deposited on the surface of inorganic membranes (PEM, PTFE, and RC membrane) and organic membrane (CM) to investigate the continuous degradation performance of pollutants in the real environmental conditions. Results showed that the membrane permeability can be well controlled in the Co-N_x/Co₃O₄/CM, and stable oxidation activity can be maintained during the continuous catalytic systems. This paper provides some interesting results related to the catalytic modules applied for future large-scale use.

Declaration of competing interest

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The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

CRediT authorship contribution statement

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Qingbai Tian: Writing – review & editing, Software, Formal analysis, Conceptualization. BingLiang Yu: Resources, Methodology. Zhihao Li: Resources, Methodology, Formal analysis. Wei Hong: Validation, Data curation, Conceptualization. Qian Li: Validation, Supervision, Project administration, Methodology. Xing Xu: Writing – review & editing, Writing – original draft, Funding acquisition, Formal analysis, Conceptualization.

Acknowledgments

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The work was supported by National Natural Science Fundation of China (Nos. 52170086, 22308194, U22A20423), Natural Science Foundation of Shandong Province (No. ZR2021ME013), Taishan Scholars Program of Shandong Province (No. tsqn202211012), and Shandong Provincial Excellent Youth (No. ZR2022YQ47). The authors also want to thank Conghua Qi from Shiyanjia Lab (www.shiyanjia.com) for DFT analysis.

Supplementary materials

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Supplementary material associated with this article can be found, in the online version, at doi:10.1016/j.cclet.2024.110322.

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Year 2025 volume 36 Issue 6

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doi: 10.1016/j.cclet.2024.110322

Receive Date：2024-04-26
Online Date：2025-10-29
Published：2025-06-15

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Received：2024-04-26
Revised：2024-07-04
Accepted：2024-08-06

Affiliations

^a Shandong Key Laboratory of Water Pollution Control and Resource Reuse, School of Environmental Science and Engineering, Shandong University, Qingdao 266237, China

^b Henan water Conservancy Survey design Research Co., Ltd., Zhengzhou 450000, China

^c Shandong Resources and Environment Construction Group Co., Ltd., Ji’nan 250100, China

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表12种不同金属材料的力学参数

科 Family	属数 Number of genus	种数 Number of species	占总种数比例 Percentage of total species (%)	属 Genus	种数 Number of species	占总种数比例 Percentage of total species (%)
鹅膏菌科Amanitaceae	2	11	5.26	鹅膏菌属 Amanita	10	4.78
小菇科 Mycenaceae	2	12	5.74	丝盖伞属 Inocybe	5	2.39
多孔菌科 Polyporaceae	8	14	6.70	蜡蘑属 Laccaria	5	2.39
红菇科 Russulaceae	3	23	11.00	小皮伞属 Marasmius	6	2.87
				小菇属 Mycena	11	5.26
				光柄菇属 Pluteus	5	2.39
				红菇属 Russula	17	8.13
				栓菌属 Trametes	5	2.39

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Fig. 1 (a) SEM of Co-N_x/Co₃O₄ at (a) 20 µm, and (b) 5 µm. (c) SEM mappings of Co-N_x/Co₃O₄. (d) TEM images of Co-N_x/Co₃O₄ as well as the specific crystal lattices of Co₃O₄. (e) Fabrication procedures for Co-N_x/Co₃O₄/PEM, Co-N_x/Co₃O₄/RC, and Co-N_x/Co₃O₄/PTFE membranes. (f) Fabrication procedures for Co-N_x/Co₃O₄/CM via airbrush spraying routine.

Fig. 2 Cross section SEM images of (a) Co-N_x/Co₃O₄/PEM, (b) Co-N_x/Co₃O₄/RC, (c) Co-N_x/Co₃O₄/PTFE. The contact angles of (d) bare PEM membrane and Co-N_x/Co₃O₄/PEM membrane, (e) bare RC membrane and Co-N_x/Co₃O₄/RC membrane, (f) bare PTFE membrane and Co-N_x/Co₃O₄/PTFE membrane.

Fig. 3 Fluxes of (a, b) Co-N_x/Co₃O₄/CR, (c, d) Co-N_x/Co₃O₄/PTFE, (e, f) Co-N_x/Co₃O₄/PES and (g, h) Co-N_x/Co₃O₄/CM membranes.

Fig. 4 (a) Scheme of the Co-N_x/Co₃O₄/CM equipped with residual PMS consumption device. (b) Residual PMS in the effluent after treatment. (c) Degradation of TC in secondary effluent via Co-N_x/Co₃O₄/CM/PMS system (Pollutant concentrations in feeding solution: 0.25 mg/L).

Fig. 5 (a) SEM cross section image of used Co-N_x/Co₃O₄/CM. (b) Degradation mechanism of Co-N_x/Co₃O₄/CM towards pollutants via PMS activation. (c) Multiple adsorption models for PMS by Co₃O₄ and Co-N_x/Co₃O₄.

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