Next Article in Journal
Spartina alterniflora-Derived Carbons for High-Performance Oxygen Reduction Reaction (ORR) Catalysts
Next Article in Special Issue
UiO-67 Metal–Organic Framework as Advanced Adsorbent for Antiviral Drugs from Water Environment
Previous Article in Journal
Biodiesel Production from Waste Frying Oil (WFO) Using a Biomass Ash-Based Catalyst
Previous Article in Special Issue
Catalyst Development for Biogas Dry Reforming: A Review of Recent Progress
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Boosting Benzene’s Ozone Catalytic Oxidation at Mild Temperatures over Highly Dispersed Ag-Doped Mn3O4

1
School of Chemical Engineering and Technology, Xinjiang University, Urumqi 830017, China
2
Xinjiang Key Laboratory of Coal Clean Conversion & Chemical Engineering Process, Urumchi 830017, China
3
Department of Energy and Material Sciences, Faculty of Engineering Sciences, Kyushu University, Fukuoka 816-8580, Japan
4
Research Center for Combustion and Environmental Technology, School of Mechanical Engineering, Shanghai Jiao Tong University, Shanghai 200240, China
5
Xinjiang Academy of Environmental Protection Sciences, Urumqi 830011, China
6
College of Ecology and Environment, Xinjiang University, Urumqi 830017, China
*
Authors to whom correspondence should be addressed.
Catalysts 2024, 14(9), 554; https://doi.org/10.3390/catal14090554
Submission received: 30 July 2024 / Revised: 18 August 2024 / Accepted: 20 August 2024 / Published: 23 August 2024
(This article belongs to the Special Issue Catalytic Energy Conversion and Catalytic Environmental Purification)

Abstract

:
Transition metal oxides show high activity while still facing the challenges of low mineralization and poor durability in the ozone catalytic oxidation (OCO) of volatile organic compounds (VOCs). Improving the oxygen mobility and low-temperature reducibility of transition metal oxides was found to be an effective way to address the above challenges. Here, highly dispersed Ag was added to Mn3O4 via the co-precipitation oxalate route, and the obtained Ag/Mn3O4 exhibited higher mineralization and stability in benzene catalytic ozonation at room temperature. Compared to Mn3O4, the concentration of CO2 formed from benzene oxidation over Ag/Mn3O4 was significantly increased, from 585.4 ppm to 810.9 ppm, while CO generation was greatly suppressed to only one tenth of its original value (194 ppm vs. 19 ppm). In addition, Ag/Mn3O4 exhibited higher catalytic stability than Mn3O4. The introduction of Ag obviously improved the oxygen mobility and low-temperature reducibility of Mn3O4. Moreover, the highly dispersed Ag also promoted the activity of surface oxygen species and the chemisorption of benzene on Mn3O4. The above physicochemical properties contributed to the excellent catalytic performance and durability of Ag/Mn3O4. This research could shed light on the improvement in VOC mineralization via ozone catalytic oxidation.

1. Introduction

Volatile organic compounds (VOCs), typically emitted from paint shops, oil refineries, etc., are considered precursors of photochemical smog and haze and could cause serious harm to both humans and the eco-environment [1,2]. VOCs not only have a high potential to form ozone and particulate matter (PM2.5) but also exhibit toxicity and carcinogenicity [3,4]. Therefore, the governments in many countries have implemented strict measures and extremely low emission limits to control VOC pollution. Currently, there are various treatment methods for VOCs, such as adsorption, catalytic oxidation, combustion, and so on [5,6]. Among the numerous VOC removal technologies, ozone catalytic oxidation (OCO) exhibited several advantages. For example, during the OCO process, O3 can be decomposed into oxygen atoms and further transformed into a variety of powerful reactive oxygen species (ROS), which can precisely and effectively react with the VOCs at near-room temperature, thus ensuring energy efficiency and safety [7,8]. Consequently, OCO has been extensively investigated for the removal of various types of VOCs, such as formaldehyde, methyl mercaptan, dichloroethane, aromatic VOCs, etc. [9,10,11,12].
Catalysts play an important role in the OCO of VOCs. In general, noble metal catalysts such as Pt, Pd, and Rh always show excellent performance, but the high price and the disadvantage of easy poisoning limit their practical application [13]. Compared to noble metal catalysts, transition metal oxides (Mn, Co, Ni, etc.) show several advantages, such as a preferential reducibility, abundant oxygen species, a high anti-poisoning ability, and so on. Moreover, the cost of these transition metal oxides is also lower than that of noble metals [14]. Therefore, transition metal oxides have been widely applied in the OCO of VOCs.
Among the various transition metal oxides, MnOx usually exerts multiple manganese oxidation states, resulting in fruit oxygen vacancies as well as strong low-temperature reducibility, which are key factors for the redox steps of VOC ozonation [15,16]. Compared to other MnOx such as Mn2O3 and MnO2, Mn3O4 was reported to facilitate the reactions between VOC molecules and ozone to form surface-adsorbed oxygen atomic species, which could be more easily and deeply oxidized [17]. However, Mn3O4 usually suffered from the incomplete oxidation of VOC molecules, low ozone utilization, and severe instability, which prevented its further application in OCO technology [18]. As a result, further research should be conducted to improve both the catalytic activity and stability of Mn3O4.
It is widely accepted that the addition of another suitable metal could always promote the catalytic activity and durability of single-metal oxides, which would be attributed to the “electronic effect” and “geometric effect” [19,20]. Thus, many transition metals have been introduced to modify the Mn3O4 in ozone decomposition, such as Cu, Fe, Ce, and so on [21,22]. For example, Fu et al. found that the partial substitution of Mn by Fe in Mn3O4 could result in abundant oxygen species and active sites of Mn3+, thus greatly promoting ozone decomposition [23]. Of all the transition metals, Ag has distinctive characteristics. It has been reported that Ag-containing catalysts usually have quantities of active sites with high activity in ozone decomposition or the OCO of VOCs [24]. In addition, the application of Ag could also promote the chemisorption of VOCs, which is a crucial step in the OCO process [10]. Therefore, Ag was introduced into manganese oxides, and the synthesized Ag-Mn catalysts were applied to ozone decomposition. Xie et al. argued that the deposition of Ag on Mn3O4 nanosheets noticeably improved the reducibility and generated more highly active oxygen vacancies; thus, the obtained Mn3O4@Ag exhibited excellent and stable catalytic performance in O3 decomposition [25]. Moreover, Liu et al. reported that the OCO of VOCs involves ozone decomposition and the oxidation of VOC molecules [7]. Therefore, the higher catalytic performance of Ag/Mn3O4 in ozone decomposition also indicated its potential in the OCO of VOCs.
In this paper, highly dispersed Ag was added to Mn3O4 via the co-precipitation oxalate route, and the obtained Ag/Mn3O4 catalyst was then applied to the OCO of benzene. The introduction of Ag greatly improved benzene mineralization, with much less by-products, and the catalytic stability of Mn3O4 at room temperature, which was attributed to the promoted oxygen mobility, enhanced low-temperature reducibility, activated surface oxygen species, and enhanced chemisorption of benzene. This work provides us with a new way to improve VOC mineralization with low by-products and catalytic durability in the OCO of VOCs.

2. Results and Discussions

2.1. Crystal Phase and Textures of Mn3O4-Based Catalysts

The XRD patterns and N2 adsorption/desorption isotherms and pore size distributions are shown in Figure 1. From Figure 1a, the Mn3O4, Ag/Mn3O4 somewhat showed the same XRD patterns as standard cubic Mn3O4 (PDF # 18-0803) according to the analysis results of Jade 6.5, indicating that Ag doping did not change the crystal phase of manganese oxide. In addition, the diffraction peaks assigned to Ag or Ag2O could hardly be observed, indicating the high dispersion of Ag in Mn3O4 [26].
The N2 adsorption/desorption isotherms of the two catalysts in Figure 1b are both type IV with H3 hysteresis loops within a wide relative pressure range of 0.4–1.0, implying the development of mesoporous structures after calcination [27]. Notably, Mn3O4 showed a specific surface area of 385.2 m2·g−1, while Ag doping resulted only in a slight decrease in the specific surface area of Ag/Mn3O4 (see Table 1). The results were beneficial to the adsorption of ozone and benzene, and the higher specific surface area would also provide more active sites to promote the OCO of benzene.
Figure 2 shows the high-resolution TEM (HRTEM) image and high-angle annular dark-field STEM images of Ag/Mn3O4, respectively. As shown in Figure 2b, the interplanar spacings were 0.299 nm and 0.253 nm, which were very close to the (2 2 0) and (3 1 1) crystal planes of Mn3O4 (PDF # 13-0162), respectively. Furthermore, the dispersion of Ag was uniform, without any agglomeration, as shown in Figure 2b,d, which was in somewhat of an agreement with the XRD results in Table 1. Summary of BJH parameters of Mn3O4 and Ag/Mn3O4.

2.2. Surface Chemical Properties of the Obtained Catalysts

The surface chemical compositions, apparent element concentration and valence, and oxygen species of the two samples were determined by the XPS technique. The Mn 2p, Ag 3d, and O 1s spectra of Mn3O4 and Ag/Mn3O4 are shown in Figure 3, and the quantitative analysis results are summarized in Table 2.
As seen in Figure 3a, the asymmetric Mn 2p 3/2 spectra of the two catalysts can be decomposed into two symmetric peaks ranging from 641.5 to 641.8 eV and from 643.0 to 643.3 eV, which should be attributed to the surface Mn3+ and Mn4+, respectively [28,29]. As shown in Table 2, Ag doping resulted in a higher proportion of surface Mn4+ compared to Mn3O4, and the result was favorable for the formation of oxygen vacancies due to the charge compensation principle [30]. Furthermore, the higher-valence manganese ions were reported to be in the form of Mn4+-Osurf. (surface oxygen species) Lewis acid–base pairs, which could efficiently activate O3 [14]. Notably, the Ag 3d 5/2 spectra in Figure 3b show only one peak, centered at 367.4 eV, which could correspond to Ag+ [31]. As shown in Table 2, the surface ratio of Ag+ to Mnn+ was very close to the designed value, indicating that the co-precipitation method via the oxalate route could make the Ag uniformly dispersed in both the bulk and apparent phases. Ag or other noble metal nanoparticles with higher surface energy often agglomerate and form large-sized particles as a result of Ostwald ripening [32]. Considering the analysis results of XRD, HAADF-STEM, and XPS, it can be concluded that Ag doping through the oxalate route could avoid the formation of Ag agglomeration.
The O 1s XPS spectra of Mn3O4 and Ag/Mn3O4 shown in Figure 3c could be fitted with two main symmetrical peaks, and the peaks centered at 529.5–529.8 eV should be surface lattice oxygen species (denoted as Oα), while the peaks at 530.6–531.2 eV are assigned as surface adsorbed oxygen species or oxygen vacancies (denoted as Oα) [33,34]. In addition, the O 1s spectra of Ag/Mn3O4 also showed another peak centered at about 533.7 eV, which was widely accepted as surface-adsorbed OH/oxy-carbonate species [35]. Noticeably, the total amount of surface-adsorbed oxygen species/vacancies (including both Oβ and Oγ) of Ag/Mn3O4 was larger than that of Mn3O4 displayed in Table 2, indicating that Ag doping not only made the surface oxygen species more active but also increased the ratio of more active adsorbed oxygen species. The above analysis results of the O 1s XPS spectra are somewhat consistent with those of the Mn 2p XPS spectra. Many researchers have proven that surface adsorbed oxygen species/vacancies and surface OH/oxy-carbonate species are beneficial for both O3 activation and VOC catalytic oxidation [36,37]. Thus, we can expect a satisfactory catalytic performance of Ag/Mn3O4.

2.3. Evolution of Oxygen Species and Reducibility of the Gained Catalysts

The evolution of the surface oxygen species of the two catalysts was investigated by the O2-TPD technique, and the results are shown in Figure 4a. In general, the desorption of adsorbed oxygen species occurred at temperatures ranging from 200 to 400 °C, while the surface lattice oxygen species usually desorbed at temperatures ranging from 400 to 600 °C [38,39]. For the Mn3O4 sample, the peak centered at 276 and 498 °C should represent the desorption of adsorbed oxygen species and lattice oxygen species, respectively. In comparison, the desorption peak of adsorbed oxygen species from Ag/Mn3O4 at 325 °C, with an obvious shoulder at 241 °C, indicated that the introduction of Ag into Mn3O4 resulted in surface oxygen species with a higher reactivity. It is widely accepted that active surface oxygen species would not only generate unsaturated chemical bonds but also lead to unbalanced charges, which would ultimately make the decomposition of ozone as well as the redox reactions occur more easily [40,41]. Since the surface oxygen species of Ag/Mn3O4 showed a higher activity than that of Mn3O4, the former sample would exert a better catalytic performance in the OCO of benzene.
The reducibility, which could be detected by the H2-TPR technique, played an important role in the catalytic oxidation of VOCs, and the H2-TPR curves of Mn3O4 and Ag/Mn3O4 are shown in Figure 4b. The reduction of Mnn+ by H2 usually followed the order of Mn4+→Mn3+→Mn2+ [42,43]. For sample Mn3O4, the first reduction peak at 275 °C with a shoulder at 180 °C should represent the reduction of the Mn3+ located in the lattice sites to Mn2+, and the latter peak, centered at 431 °C, could be assigned to the final reduction of Mn3+ to Mn2+ [44]. With Ag doping, the reduction peaks of Ag/Mn3O4 were shifted to lower temperatures compared to those of Mn3O4. In other words, the Ag/Mn3O4 catalyst in this research exerted a much better low-temperature reducibility, bringing a positive effect to the subsequent OCO of benzene.

2.4. Temperature-Programmed Surface Reaction on the Obtained Catalysts

To illustrate the activity of surface oxygen species and the adsorption/desorption behavior of benzene on the as-prepared catalysts, the C6H6-TPSR technique was introduced, and the profiles are shown in Figure 5.
As shown in Figure 5, the desorption of benzene from Ag/Mn3O4 had a larger peak than that of Mn3O4, which was inconsistent with their pore volumes in Table 1. The CO2 was probably formed from the reaction between chemisorbed benzene and adsorbed surface oxygen species, considering both the C6H6-TPSR process and the O2-TPD results [45,46]. Apparently, sample Ag/Mn3O4 showed a higher CO2 desorption but a lower peak temperature than Mn3O4 under the N2 atmosphere, indicating that the surface oxygen species of the former catalyst was more active than that of the latter. In addition, the introduction of Ag also provided more active sites, which was beneficial for the chemisorption of benzene [47]. Researchers have demonstrated that active surface oxygen species could easily react with VOC molecules and that the formed oxygen vacancies would be favorable for ozone decomposition, which, in turn, would be beneficial for benzene ozonation [48].

2.5. Catalytic Performance of Benzene OCO

The performance of benzene OCO over the two obtained catalysts is shown in Figure 6, and some important related data are summarized in Table 3.
From Figure 6a,c, it can be seen that the benzene removal efficiencies over Mn3O4 and Ag/Mn3O4 rapidly increased from 0 to nearly 100% but then gradually decreased to 91.8% and 97.4% at 25 °C after 170 min (Table 3), respectively. This is because benzene can hardly be completely mineralized by ozone at low temperatures, and some inorganic intermediates would be formed during this process on the surface active sites, leading to the gradual deactivation of the catalysts [49]. According to Einaga et al., some intermediates such as weakly bound formic acid and strongly bound formates (carboxylic acid) may be formed and accumulated on Mn-based catalysts during the OCO of benzene, and some of the above intermediates could be further oxidized to CO2 or CO at relatively higher temperatures [11]. With the consumption of these intermediates, the activity of the catalyst could be recovered, and this would be consistent with the catalytic performance of the two samples in Figure 6. Noticeably, Ag doping improved the catalytic activity and stability of Mn3O4, which might have been due to the active oxygen species on Ag/Mn3O4 which could easily react with the intermediates at low temperatures, and the results were in fair agreement with the O2-TPD and XPS data. Consequently, more CO2 and much less CO as a by-product were generated when Ag/Mn3O4 was applied (see Figure 6d), which might have been mainly due to more active oxygen species, according to the O2-TPD and C6H6-TPSR results. In Table 3, we can clearly see that the CO2 generation at 25 °C was about 585.4 ppm and 810.9 ppm with Mn3O4 and Ag/Mn3O4, respectively, while CO production was suppressed to only one tenth of the original value when the latter catalyst was used (19.2 ppm with Ag/Mn3O4 vs. 194.7 ppm with Mn3O4). That is to say, introducing Ag is beneficial for the complete mineralization of benzene, while also reducing the formation of by-products.
When the temperature was increased to 70 °C, the benzene conversion rates recovered rapidly to nearly 100%, and no deactivation was observed in the last 70 min (Figure 6a,c). Moreover, the elevated temperature also favored the production of CO2 and CO, which showed a sharp increase in the first 30 min and then decreased to stable, normal values. The sharp peaks for both CO2 and CO were attributed to the oxidation of some organic intermediates simulated in the catalytic oxidation of benzene at 25 °C [44]. The benzene mineralization percentage for both samples at 70 °C in the last 60 min was very close to 100%, according to the data in Table 3, but Ag/Mn3O4 also showed higher CO2 production and lower CO generation than Mn3O4. Meanwhile, nearly no O3 could be detected in the outlet, further demonstrating that the two samples exerted a satisfying catalytic performance at 70 °C.
Briefly, the Ag doping of Mn3O4 improved mineralization and durability in the OCO of benzene at mild temperatures. CO2 production was promoted while CO generation was noticeably suppressed when Ag/Mn3O4 was applied. Considering the above analysis results of the catalysts’ characterization, it can be concluded that the highly dispersed Ag in Mn3O4 resulted in more active oxygen species, which improved the oxygen mobility and low-temperature reducibility of Mn3O4. Moreover, the active oxygen species were also beneficial for the decomposition and activation of ozone, generating reactive oxygen species which could easily and rapidly react with the benzene molecules or intermediates on Ag/Mn3O4. As a result, the inorganic intermediates accumulated on the surface of Mn3O4 were quickly and deeply oxidized with Ag doping. The above factors can likely be attributed to the preferred mineralization and catalytic durability of Ag/Mn3O4 in the OCO of benzene.

3. Experimental

3.1. Catalyst Preparation

Three reagents were used in this research without further purification. The manganese nitrate solution (50 wt%, AR) and ammonium oxalate monohydrate (AR) were purchased from Sinopharm Chemical Reagent Co., Ltd., Shanghai, China. Silver nitrate (AR) was purchased from Lingfeng Chemical Reagent Co., Ltd., Shanghai, China.
The MnOx and AgMn bimetallic catalysts were synthesized by the (co)precipitation method. First, 3.58 g of manganese nitrate solution and 1.42 g of ammonium oxalate monohydrate were diluted in 100 mL of deionized water. Then, the manganese nitrate solution was added drop by drop to the oxalic acid solution while stirring, and the mixed solution was stirred for another 30 min to ensure the complete precipitation of manganese ions. Then, the mixed solution was filtered and washed three times with deionized water and once with absolute alcohol. The filtered sediment was then dried at 80 °C overnight. Finally, the dried sediment was calcined at 250 °C for 5 h under static air, with a heating rate of 2 °C·min−1. After calcination, the resulting catalyst was Mn3O4. The AgMn bimetallic catalyst with a Ag/Mn molar ratio of 1:19 was obtained by the co-precipitation method. The molar ratio of metal ions to oxalate ions was the same as that used in the preparation of Mn3O4, and it was designated as Ag/Mn3O4.

3.2. Characterizations

The XRD patterns of the obtained catalysts were recorded using a Rigaku RINT 2200 system (Rigaku Co. Ltd., Sevenoaks, UK) with a Cu Kα radiation, and the 2θ ranged from 10 to 80°. In addition, N2 adsorption/desorption isotherms were performed using a Micromeritics TriStar II, and the sample was degassed at 200 °C for 1 h prior to measurement. High-resolution transmission electron microscopy (JEM-ARM200F, JEOL) was used to determine the microstructures and interplanar spacings of the as-prepared samples. Oxygen temperature-programmed desorption was carried out using a BELCAT-30 flow-type catalyst analyzer (BEL JAPAN, Inc., Haradanaka, Toyonaka-shi, Japan); both obtained catalysts were pretreated under Ar flow at 250 °C for 1 h before testing. In the O2-TPD test, the atmosphere was changed to 5% O2/N2 when the pretreated catalyst was cooled to r.t. The Ar flow was turned on again when the adsorption of oxygen on the pretreated catalyst reached dynamic equilibrium. Finally, the data were recorded at a temperature ranging from r.t. to 600 °C. The pretreatment of the catalyst during the H2-TPR test was the same as that of O2-TPD. The H2-TPR signal was marked down when the Ar flow was replaced by 5% H2/N2, and the operating temperature also ranged from r.t. to 600 °C. X-ray photoelectron spectroscopy (XPS, AXIS UltraDLD, Kratos group, Spring Valley, NV, USA) was used to determine the metal oxidation states, chemical composition, and surface oxygen species of the as-prepared catalysts. In addition, a C6H6 temperature-programmed surface reaction (C6H6-TPSR) was performed using FTIR (Perkin-Elmer, Spectrum 100, Waltham, MA, USA), with a gas cell at a resolution of 4 cm−1.

3.3. Catalytic Activity Measurements

The catalytic performance test of the synthesized catalysts (40–60 mesh) was carried out in a U-type quartz tube fixed-bed reactor with an inner diameter of 8 mm. In each test, 100 mg of the selected sample was used and heated at 250 °C in simulated air for 1 h. The temperature was maintained at 25 °C for some time and then increased to 70 °C until the end of the test. The weight hourly space velocity (WHSV) in this research was 60,000 mL·gcat−1·h−1, and the reaction air flow was 100 mL·min−1, with an initial benzene concentration of 200 ppm. The ozone was generated by a UV lamp, and the initial concentration was 2200 ppm. The compositions (C6H6, CO, CO2, etc.) of the downstream flow were analyzed online using an FTIR spectrometer (Perkin-Elmer, Waltham, MA, USA, resolution of 4 cm−1) equipped with a gas cell (2 m path length), while the residual ozone was measured using an ozone analyzer (EG-600, Ebara Jitsugyo, Japan). Prior to the tests, the potential compositions were calibrated with standard C6H6, CO, CO2, etc. In addition, the benzene removal efficiency, CO2 selectivity, and COx (CO2 + CO) selectivity were calculated using the following equations [44]:
η C 6 H 6 = 200 C C 6 H 6 200 × 100 %
S C O 2 = C C O 2 6 × 200 C C 6 H 6 × 100 %
S C O x = C C O 2 + C C O 6 × 200 C C 6 H 6 × 100 %
where CC6H6, CCO2, and CCO were the initial concentrations of benzene, CO2, and CO, respectively, after the reaction became stabilized.

4. Conclusions

Ag/Mn3O4 was synthesized by the co-precipitation oxalate route and applied to benzene OCO. Ag doping greatly improved crucial physicochemical properties of Mn3O4, such as better low-temperature reducibility, oxygen mobility, and surface active oxygen species, and promoted the chemisorption of benzene. As a result, Ag/Mn3O4 exhibited an excellent catalytic performance in the OCO of benzene at mild temperatures. For example, CO2 generation was 585.4 ppm with Mn3O4, while it increased to 810.9 ppm when Ag/Mn3O4 was used. Meanwhile, CO generation was strongly suppressed to one tenth of its original value (194 ppm vs. 19 ppm). The addition of Ag species to Mn3O4 could lead to higher benzene mineralization during the OCO process. Moreover, Ag/Mn3O4 also exerted an improved catalytic durability, indicating that the surface intermediates oxidized faster than those on Mn3O4.

Author Contributions

Conceptualization, W.S., H.H. (Haibao Huang) and H.E.; methodology, H.G.; investigation, L.C., K.D. and W.M.; writing—original draft preparation, H.G. and P.Z.; writing—review and editing, D.H., H.H. (Haibao Huang) and H. Hojo; supervision, W.S., H.H. (Haibao Huang) and H.E.; funding acquisition, H.G. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by Natural Science Foundation of Xinjiang Uygur Autonomous Region (2021D01C036).

Data Availability Statement

No data were created.

Acknowledgments

This work was financially supported by the Natural Science Foundation of Xinjiang Uygur’s Autonomous Region (2021D01C036).

Conflicts of Interest

We declare that we have no commercial or associative interests that would constitute conflicts of interest in connection with the submitted work.

References

  1. Wang, P.; Ma, X.; Hao, X.; Tang, B.; Abudula, A.; Guan, G. Oxygen vacancy defect engineering to promote catalytic activity toward the oxidation of VOCs: A critical review. Catal. Rev. 2024, 66, 586–639. [Google Scholar] [CrossRef]
  2. Lin, F.; Xiang, L.; Zhang, Z.; Li, N.; Yan, B.; He, C.; Hao, Z.; Chen, G. Comprehensive review on catalytic degradation of Cl-VOCs under the practical application conditions. Crit. Rev. Environ. Sci. Technol. 2022, 52, 311–355. [Google Scholar] [CrossRef]
  3. He, C.; Cheng, J.; Zhang, X.; Douthwaite, M.; Pattisson, S.; Hao, Z. Recent advances in the catalytic oxidation of volatile organic compounds: A review based on pollutant sorts and sources. Chem. Rev. 2019, 119, 4471–4568. [Google Scholar] [CrossRef]
  4. Wei, W.; Chen, S.; Wang, Y.; Cheng, L.; Wang, X.; Cheng, S. The impacts of VOCs on PM2.5 increasing via their chemical losses estimates: A case study in a typical industrial city of China. Atmos. Environ. 2022, 273, 118978. [Google Scholar] [CrossRef]
  5. Zhu, L.; Shen, D.; Luo, K.H. A critical review on VOCs adsorption by different porous materials: Species, mechanisms and modification methods. J. Hazard. Mater. 2020, 389, 122102. [Google Scholar] [CrossRef]
  6. Zhao, Z.; Ma, S.; Gao, B.; Bi, F.; Qiao, R.; Yang, Y.; Wu, M.; Zhang, X. A systematic review of intermediates and their characterization methods in VOCs degradation by different catalytic technologies. Sep. Purif. Technol. 2023, 314, 123510. [Google Scholar] [CrossRef]
  7. Liu, B.; Ji, J.; Zhang, B.; Huang, W.; Gan, Y.; Leung, D.Y.C.; Huang, H. Catalytic ozonation of VOCs at low temperature: A comprehensive review. J. Hazard. Mater. 2022, 422, 126847. [Google Scholar] [CrossRef]
  8. Dai, W.; Zhang, B.; Ji, J.; Liu, B.; Xie, R.; Gan, Y.; Xie, X.; Zhang, J.; Huang, P.; Huang, H. Exceptional ozone decomposition over δ-MnO2/AC under an entire humidity environment. Environ. Sci. Technol. 2023, 57, 17727–17736. [Google Scholar] [CrossRef] [PubMed]
  9. Lin, F.; Zhang, Z.; Xiang, L.; Zhang, L.; Cheng, Z.; Wang, Z.; Yan, B.; Chen, G. Efficient degradation of multiple Cl-VOCs by catalytic ozonation over MnOx catalysts with different supports. Chem. Eng. J. 2022, 435, 134807. [Google Scholar] [CrossRef]
  10. Xia, D.; Xu, W.; Wang, Y.; Yang, J.; Huang, Y.; Hu, L.; He, C.; Shu, D.; Leung, D.Y.C.; Pang, Z. Enhanced performance and conversion pathway for catalytic ozonation of methyl mercaptan on single-atom Ag deposited three-dimensional ordered mesoporous MnO2. Environ. Sci. Technol. 2018, 52, 13399–13409. [Google Scholar] [CrossRef]
  11. Einaga, H.; Teraoka, Y.; Ogata, A. Catalytic oxidation of benzene by ozone over manganese oxides supported on USY zeolite. J. Catal. 2013, 305, 227–237. [Google Scholar] [CrossRef]
  12. Fan, G.; Guo, Y.; Chai, S.; Zhang, L.; Guan, J.; Ma, G.; Han, N.; Chen, Y. Synthesis of δ-MnO2 via ozonation routine for low temperature formaldehyde removal. J. Environ. Sci. 2025, 147, 642–651. [Google Scholar] [CrossRef]
  13. Hu, P.; Amghouz, Z.; Huang, Z.; Xu, F.; Chen, Y.; Tang, X. Surface-confined atomic silver centers catalyzing formaldehyde oxidation. Environ. Sci. Technol. 2015, 49, 2384–2390. [Google Scholar] [CrossRef]
  14. Chen, W.; He, H.; Liang, J.; Wei, X.; Li, X.; Wang, J.; Li, L. A comprehensive review on metal based active sites and their interaction with O3 during heterogeneous catalytic ozonation process: Types, regulation and authentication. J. Hazard. Mater. 2023, 443, 130302. [Google Scholar] [CrossRef] [PubMed]
  15. Gopi, T.; Swetha, G.; Chandra, S.S.; Ramakrishna, C.; Saini, B.; Krishna, R.; Rao, P.V.L. Catalytic decomposition of ozone on nanostructured potassium and proton containing δ-MnO2 catalysts. Catal. Commun. 2017, 92, 51–55. [Google Scholar] [CrossRef]
  16. Jia, J.; Zhang, P.; Chen, L. Catalytic decomposition of gaseous ozone over manganese dioxides with different crystal structures. Appl. Catal. B 2016, 189, 210–218. [Google Scholar] [CrossRef]
  17. Wang, H.C.; Chang, S.H.; Hung, P.C.; Hwang, J.F.; Chang, M.B. Synergistic effect of transition metal oxides and ozone on PCDD/F destruction. J. Hazard. Mater. 2009, 164, 1452–1459. [Google Scholar] [CrossRef]
  18. Wang, Y.; Arandiyan, H.; Scott, J.; Bagheri, A.; Dai, H.; Amal, R. Recent advances in ordered meso/macroporous metal oxides for heterogeneous catalysis: A review. J. Mater. Chem. A 2017, 5, 8825–8846. [Google Scholar] [CrossRef]
  19. Liu, S.; Wu, X.; Weng, D.; Ran, R. Ceria-based catalysts for soot oxidation: A review. J. Rare Earth 2015, 33, 567–590. [Google Scholar] [CrossRef]
  20. Liu, L.; Wu, N.; Ouyang, M.; Xing, Y.; Tian, J.; Chen, P.; Wu, J.; Hu, Y.; Niu, X.; Fu, M.; et al. Enhancement effect induced by the second metal to promote ozone catalytic oxidation of VOCs. Environ. Sci. Technol. 2024, 58, 6725–6735. [Google Scholar] [CrossRef]
  21. Kim, J.; Lee, J.E.; Lee, H.W.; Jeon, J.K.; Song, J.; Jung, S.C.; Tsang, Y.F.; Park, Y.K. Catalytic ozonation of toluene using Mn-M bimetallic H-ZSM-5 (M: Fe, Cu, Ru, Ag) catalysts at room temperature. J. Hazard. Mater. 2020, 397, 122577. [Google Scholar] [CrossRef] [PubMed]
  22. Zhang, Y.; Chen, M.; Zhang, Z.; Jiang, Z.; Shangguan, W.; Einaga, H. Simultaneously catalytic decomposition of formaldehyde and ozone over manganese cerium oxides at room temperature: Promotional effect of relative humidity on the MnCeOx solid solution. Catal. Today 2019, 327, 323–333. [Google Scholar] [CrossRef]
  23. Fu, Y.; Zhong, L.; Li, Z.; Jin, H.; Liu, X.; Tong, W.; Li, X.; Zhao, S. Spinel (Mn, Fe)3O4 nanocatalyst for the catalytic ozone decomposition under humid conditions. ACS Appl. Nano Mater. 2024, 7, 7111–7721. [Google Scholar] [CrossRef]
  24. Nikolov, P.; Genov, K.; Konova, P.; Milenova, K.; Batakliev, T.; Georgiev, V.; Kumar, N.; Sarker, D.K.; Pishev, D.; Rakovsky, S. Ozone decomposition on Ag/SiO2 and Ag/clinoptilolite catalysts at ambient temperature. J. Hazard. Mater. 2010, 184, 16–19. [Google Scholar] [CrossRef]
  25. Xie, Y.; Wang, J.; Zhou, Z.; Wu, Y.; Cheng, G.; Li, Y.; Sun, C.; Sun, M.; Yu, L. Engineering of Mn3O4@Ag microspheres assembled from nanosheets for superior O3 decomposition. Dalton Trans. 2022, 51, 16612–16619. [Google Scholar] [CrossRef] [PubMed]
  26. Jiang, N.; Qiu, C.; Guo, L.; Shang, K.; Lu, N.; Li, J.; Zhang, Y.; Wu, Y. Plasma-catalytic destruction of xylene over Ag-Mn mixed oxides in a pulsed sliding discharge reactor. J. Hazard. Mater. 2019, 369, 611–620. [Google Scholar] [CrossRef]
  27. Guo, H.; Zhang, Z.; Jiang, Z.; Chen, M.; Einaga, H.; Shangguan, W. Catalytic activity of porous manganese oxides for benzene oxidation improved via citric acid solution combustion synthesis. J. Environ. Sci. 2020, 98, 196–204. [Google Scholar] [CrossRef]
  28. Li, Z.; Gao, R.; Hou, Z.; Yu, X.; Dai, H.; Deng, J.; Liu, Y. Tandem supported Pt and ZSM-5 catalyst with separated catalytic functions for promoting multicomponent VOCs oxidation. Appl. Catal. B 2023, 339, 123131. [Google Scholar] [CrossRef]
  29. Jiang, T.; Wang, X.; Zhang, J.; Mai, Y.; Chen, J. Highly efficient MnOx catalysts derived from Mn-MOFs for chlorobenzene oxidation: The influence of MOFs precursors, oxidant and doping of Ce metal. Mol. Catal. 2023, 551, 113653. [Google Scholar] [CrossRef]
  30. Tang, W.; Li, J.; Wu, X.; Chen, Y. Limited nanospace for growth of Ni-Mn composite oxide nanocrystals with enhanced catalytic activity for deep oxidation of benzene. Catal. Today 2015, 258, 148–155. [Google Scholar] [CrossRef]
  31. Li, H.; Qiao, D.; Chu, M.; Guo, L.; Sun, Z.; Fan, Y.; Ni, S.Q.; Tung, C.H.; Wang, Y. Accumulation of Ag(0) single atoms at water/mineral interfaces during sunlight-induced reduction of ionic Ag by phenolic DOM. Environ. Sci. Technol. 2023, 57, 20822–20829. [Google Scholar] [CrossRef]
  32. Hansen, T.W.; DeLaRiva, A.T.; Challa, S.R.; Datye, A.K. Sintering of catalytic nanoparticles: Particle migration or Ostwald ripening? Acc. Chem. Res. 2013, 46, 1720–1730. [Google Scholar] [CrossRef]
  33. Liu, B.; Yang, Y.; Tan, Q.; Zhou, K.; Xu, X.; Ding, Y.; Han, Y.; Fan, X.; Tao, R. Cr doped Mn3O4 thermal catalytic isopropanol degradation at low-temperature and catalytic mechanism research. Colloid Surf. A 2022, 640, 128390. [Google Scholar] [CrossRef]
  34. Yang, X.; Yu, X.; Lin, M.; Ma, X.; Ge, M. Enhancement effect of acid treatment on Mn2O3 catalyst for toluene oxidation. Catal. Today 2019, 327, 254–261. [Google Scholar] [CrossRef]
  35. Shao, S.; Li, Z.; Zhang, J.; Gao, K.; Liu, Y.; Jiao, W. Preparation of Ce-MnOx/γ-Al2O3 by high gravity-assisted impregnation method for efficient catalytic ozonation. Chem. Eng. Sci. 2022, 248, 117246. [Google Scholar] [CrossRef]
  36. Lu, J.; Hao, H.; Zhang, L.; Xu, Z.; Zhong, L.; Zhao, Y.; He, D.; Liu, J.; Chen, D.; Pu, H.; et al. The investigation of the role of basic lanthanum (La) species on the improvement of catalytic activity and stability of HZSM-5 material for eliminating methanethiol-(CH3SH). Appl. Catal. B 2018, 237, 185–197. [Google Scholar] [CrossRef]
  37. Lu, Y.; Deng, H.; Pan, T.; Liao, X.; Zhang, C.; He, H. Effective toluene ozonation over δ-MnO2: Oxygen vacancy-induced reactive oxygen species. Environ. Sci. Technol. 2023, 57, 2918–2927. [Google Scholar] [CrossRef]
  38. Zhang, Y.; Shi, J.; Fang, W.; Chen, M.; Zhang, Z.; Jiang, Z.; Shangguan, W.; Einaga, H. Simultaneous catalytic elimination of formaldehyde and ozone over one-dimensional rod-like manganese dioxide at ambient temperature. J. Chem. Technol. Biotechnol. 2019, 94, 2305–2317. [Google Scholar] [CrossRef]
  39. Zhang, X.; Zhao, H.; Song, Z.; Zhao, J.; Ma, Z.; Zhao, M.; Xing, Y.; Zhang, P.; Tsubaki, N. Influence of hydrothermal synthesis temperature on the redox and oxygen mobility properties of manganese oxides in the catalytic oxidation of toluene. Transit. Metal Chem. 2019, 44, 663–670. [Google Scholar] [CrossRef]
  40. Zhang, B.; Ji, J.; Liu, B.; Zhang, D.; Liu, S.; Huang, H. Highly efficient ozone decomposition against harsh environments over long-term stable amorphous MnOx catalysts. Appl. Catal. B 2022, 315, 121552. [Google Scholar] [CrossRef]
  41. Li, M.; Liu, X.; Niu, X.; Zhu, Y. Regulating the mobility of lattice oxygen on hollow cobalt-manganese sub-nanospheres for enhanced catalytic oxidation of toluene and o-xylene. J. Colloid Interfaces Sci. 2024, 671, 192–204. [Google Scholar] [CrossRef] [PubMed]
  42. Ji, F.; Men, Y.; Wang, J.; Sun, Y.; Wang, Z.; Zhao, B.; Tao, X.; Xu, G. Promoting diesel soot combustion efficiency by tailoring the shapes and crystal facets of nanoscale Mn3O4. Appl. Catal. B 2019, 242, 227–237. [Google Scholar] [CrossRef]
  43. Lei, J.; Chen, J.; Bai, B.; Wang, P.; Wang, S.; Li, J. Regulation of the existing state of Cu species in high water-toletant CuOx-Mn3O4 for VOCs mixtrue catalytic oxidation. Chem. Eng. Sci. 2024, 284, 119455. [Google Scholar] [CrossRef]
  44. Guo, H.; Liu, X.; Hojo, H.; Yao, X.; Einaga, H.; Shangguan, W. Removal of benzene by non-thermal plasma catalysis over manganese oxides through a facile synthesis method. Environ. Sci. Pollut. Res. 2019, 26, 8237–8247. [Google Scholar] [CrossRef]
  45. Wang, J.; Su, J.; Zhao, G.; Liu, D.; Yuan, H.; Kuvarega, A.T.; Mamba, B.B.; Li, H.; Gui, J. A facile method for preparing the CeMnO3 catalyst with high activity and stability of toluene oxidation: The critical role of small crystal size and Mn3+-Ov-Ce4+ sites. J. Hazard. Mater. 2024, 470, 134114. [Google Scholar] [CrossRef]
  46. Hu, Z.; Mi, R.; Yong, X.; Liu, S.; Li, D.; Li, Y.; Zhang, T. Effect of crystal phase of MnO2 with similar nanorod-shaped morphology on the catalytic performance of benzene combustion. ChemistrySelect 2019, 4, 473–480. [Google Scholar] [CrossRef]
  47. Perupogu, V.; Rajendiran, R.; Balla, P.; Seelam, P.K.; Aravindh, A.; Kim, S.; Pinapati, S.R.; Nakka, L. Insight into the role of metal support interface on shape dependent MnO2 support through the synergistic effect between Ag and MnO2 for the total oxidation of propane. J. Environ. Chem. Eng. 2024, 12, 112655. [Google Scholar] [CrossRef]
  48. Shao, Q.; Cheng, Z.; Gao, L.; Li, T.; Zhang, J.; Long, C. Tuning the properties of oxygen vacancy around Cu-Mn mixed oxides on dealumination Y zeolite by P-doping to achieve ultra-efficient catalytic ozonation of toluene with low ozone consumption. Appl. Catal. B 2023, 339, 123154. [Google Scholar] [CrossRef]
  49. Trinh, Q.H.; Mok, Y.S. Effect of the adsorbent/catalyst preparation method and plasma reactor configuration on the removal of dilute ethylene from air stream. Catal. Today 2015, 256, 170–177. [Google Scholar] [CrossRef]
Figure 1. XRD spectra (a) and N2-adsorption/desorption isotherms (b), inset pore size distribution curves) of the obtained catalysts.
Figure 1. XRD spectra (a) and N2-adsorption/desorption isotherms (b), inset pore size distribution curves) of the obtained catalysts.
Catalysts 14 00554 g001
Figure 2. HRTEM image (a), HAADF-STEM image (b), and elemental mapping ((c): Mn, (d): Ag) of Ag/Mn3O4.
Figure 2. HRTEM image (a), HAADF-STEM image (b), and elemental mapping ((c): Mn, (d): Ag) of Ag/Mn3O4.
Catalysts 14 00554 g002
Figure 3. XPS curves of Mn3O4 and Ag/Mn3O4 ((a): Mn 2p 3/2; (b): Ag 2d 5/2; and (c): O 1 s).
Figure 3. XPS curves of Mn3O4 and Ag/Mn3O4 ((a): Mn 2p 3/2; (b): Ag 2d 5/2; and (c): O 1 s).
Catalysts 14 00554 g003
Figure 4. O2-TPD (a) and H2-TPR (b) profiles of as-prepared catalysts.
Figure 4. O2-TPD (a) and H2-TPR (b) profiles of as-prepared catalysts.
Catalysts 14 00554 g004
Figure 5. C6H6-TPSR profiles of Mn3O4 (a) and Ag/Mn3O4 (b).
Figure 5. C6H6-TPSR profiles of Mn3O4 (a) and Ag/Mn3O4 (b).
Catalysts 14 00554 g005
Figure 6. Benzene conversion and concentrations of CO2, CO, and O3 as a function of time at 25 °C and 70 °C, respectively ((a,b): Mn3O4; (c,d): Ag/Mn3O4).
Figure 6. Benzene conversion and concentrations of CO2, CO, and O3 as a function of time at 25 °C and 70 °C, respectively ((a,b): Mn3O4; (c,d): Ag/Mn3O4).
Catalysts 14 00554 g006
Table 1. Summary of BJH parameters of Mn3O4 and Ag/Mn3O4.
Table 1. Summary of BJH parameters of Mn3O4 and Ag/Mn3O4.
SampleSpecific Surface Area/m2·g−1Pore Volume/cm3·g−1Average Pore Size/nm
Mn3O4385.20.404.2
Ag/Mn3O4372.40.444.8
Table 2. Summary of the XPS analysis results.
Table 2. Summary of the XPS analysis results.
CatalystMn3+Mn4+Ag+OαOβ + Oγ
BE/eV%BE/eV%BE/eV% §1BE/eV%BE/eV%
Mn3O4641.879.81643.320.19--529.866.1531.233.9
Ag/Mn3O4641.575.70643.024.30367.45.01529.557.0530.643.0
§1: The ratio of surface Ag+ to the total surface metal ions.
Table 3. Summary of benzene OCO with two samples at 25 °C and 70 °C, respectively.
Table 3. Summary of benzene OCO with two samples at 25 °C and 70 °C, respectively.
Sample25 °C70 °C
C6H6 rem./% §2CO2 /ppmCO /ppmRes. O3/ppmC6H6 rem./% §3CO2 /ppmCO /ppmRes. O3/ppm
Mn3O491.8585.4194.7270.299.81046.4301.40
Ag/Mn3O497.4810.919.267.299.81165.4157.50
§2 The value was measured after the OCO of benzene lasted for 170 min at 25 °C. §3 The benzene removal efficiency was detected after the OCO of benzene lasted for 70 min at 70 °C.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Guo, H.; Cen, L.; Deng, K.; Mo, W.; Hajime, H.; Hu, D.; Zhang, P.; Shangguan, W.; Huang, H.; Einaga, H. Boosting Benzene’s Ozone Catalytic Oxidation at Mild Temperatures over Highly Dispersed Ag-Doped Mn3O4. Catalysts 2024, 14, 554. https://doi.org/10.3390/catal14090554

AMA Style

Guo H, Cen L, Deng K, Mo W, Hajime H, Hu D, Zhang P, Shangguan W, Huang H, Einaga H. Boosting Benzene’s Ozone Catalytic Oxidation at Mild Temperatures over Highly Dispersed Ag-Doped Mn3O4. Catalysts. 2024; 14(9):554. https://doi.org/10.3390/catal14090554

Chicago/Turabian Style

Guo, Hao, Liwei Cen, Kui Deng, Wenlong Mo, Hojo Hajime, Di Hu, Pan Zhang, Wenfeng Shangguan, Haibao Huang, and Hisahiro Einaga. 2024. "Boosting Benzene’s Ozone Catalytic Oxidation at Mild Temperatures over Highly Dispersed Ag-Doped Mn3O4" Catalysts 14, no. 9: 554. https://doi.org/10.3390/catal14090554

APA Style

Guo, H., Cen, L., Deng, K., Mo, W., Hajime, H., Hu, D., Zhang, P., Shangguan, W., Huang, H., & Einaga, H. (2024). Boosting Benzene’s Ozone Catalytic Oxidation at Mild Temperatures over Highly Dispersed Ag-Doped Mn3O4. Catalysts, 14(9), 554. https://doi.org/10.3390/catal14090554

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop