Cordierite Catalysts for

Mar 7, 2018 - Department of Environmental Engineering, School of Energy and Environmental Engineering, University of Science and Technology Beijing , ...
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Kinetics, Catalysis, and Reaction Engineering

Improving the Efficiency of Mn-CeOx/Cordierite Catalysts for Non-methane Hydrocarbon oxidation in Cooking Oil Fumes Honghong Yi, Yonghai Huang, Xiaolong Tang, Shunzheng Zhao, Fengyu Gao, Jiangen Wang, and Zhongyu Yang Ind. Eng. Chem. Res., Just Accepted Manuscript • DOI: 10.1021/acs.iecr.7b04904 • Publication Date (Web): 07 Mar 2018 Downloaded from http://pubs.acs.org on March 7, 2018

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Improving the Efficiency of Mn-CeOx/Cordierite Catalysts for Non-methane Hydrocarbon oxidation in Cooking Oil Fumes Honghong Yia,b, Yonghai Huanga, Xiaolong Tanga,b*, Shunzheng Zhaoa,b, Fengyu Gaoa, Jiangen Wanga, Zhongyu Yanga a

Department of Environmental Engineering, School of Energy and Environmental Engineering, University

of Science and Technology Beijing, Beijing 100083, PR China b

Beijing Key Laboratory of Resource-oriented Treatment of Industrial Pollutants, Beijing 100083, PR

China Corresponding Author: Xiaolong Tang Tel./fax:+86 010 62332747. E-mail address: [email protected].

ABSTRACT Cooking oil fumes (COFs) are considered as one of the important pollution sources in urban area and non-methane hydrocarbon (NMHC) can be an index of volatile organic compounds (VOCs) from COFs. In this paper, cordierite supported Mn-CeOx catalysts were used for NMHC oxidation in COFs. The results showed that the catalytic oxidation activity of Mn-CeOx/cordierite was obviously improved by adding an appropriate proportion of Ce. The catalytic activity of Mn4Ce1/C was obviously better than catalysts with other molar ratios of Mn/Ce and Mn/C because of the extra adsorbed oxygen species and high ratio of Ce4+/Ce3+ according to the XPS analysis. The physisorption of N2 and SEM-EDS revealed the structure of catalysts prepared by a sol-gel method presented the higher BET specific surface area, more abundant pore structure and better dispersion of catalysts’ active components which were favorable for catalytic oxidation reaction of NMHC. Keywords: NMHC, Cooking oil fumes, Mn-Ce catalyst, Catalytic oxidation 1. Introduction The degradation of air quality has become an important environmental problem in recent years in China, especially in the metropolitan regions1-3. In urban areas, cooking oil fumes (COFs) have been considered as one of the important domestic pollution sources for particulate matter (PM) and volatile organic compounds (VOCs). There are many kinds of VOCs, such as hydrocarbons, aldehydes, ketones, acids, etc., in COFs.4-7. Non-methane hydrocarbon (NMHC) is an important component of VOCs which can used as a standard of 1

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the VOCs concentration and can result in the photochemical reactions with NOx, the generation of tropospheric ozone and secondary organic aerosol (SOA)8-10, and also are harmful to both human health and the environment with the components of benzene, toluene, xylenes et al11-13. The commonly used COFs purification technologies including mechanical cleaning, electrostatic deposition, and filtration adsorption have some disadvantages, such as large size, high operating costs and relatively low removal efficiency of VOCs6, 8. Thus, it is necessary to develop a more environmentally friendly and effective COFs purification technology. Catalytic combustion has been proved as an environmentally friendly method for the removal of COFs due to its low power consumption, avoiding of NOx generation and high purification efficiency of VOCs14, 15, in which the catalyst is the technological core. Manganese oxide has been recognized as a kind of excellent catalyst in the transition metal oxides attributed to its variety oxidation states, abundant lattice oxygen and surface adsorption oxygen species and oxygen vacancies provided by lattice defects16-19. As a catalytic promoter, ceria (CeO2) can not only improve the high ability of oxygen storage/release capacity and good capacity for oxygen delivery, but also promote the oxidation-reduction properties between Ce4+ and Ce3+.20-22 In order to simulate the real situation of COFs, the most commonly used soybean oil in China was chosen to generate COFs by heating at 200℃. The commercial cordierites before and after nitric acid treatment were used as the catalyst supports. Catalysts with different molar ratios of Mn/Ce were prepared by incipient wetness impregnation method and different Mn4Ce1 catalysts were prepared by sol-gel method. The catalytic activity of all the catalysts and catalyst supports using for NMHC oxidation in COFs was investigated. In order to analyze how the Mn/Ce molar ratios of catalysts and different catalyst preparation method affect the catalysts’ catalytic performance, all the samples were characterized by physisorption of N2, SEM, EDS, XRD and XPS. In addition, this paper was expected to promote the efficiency of COFs purification so as to improve the air quality in the metropolitan areas. 2. Experimental 2.1 Catalyst preparation The commercial cordierite support (TENNECO, 64 cells per Square centimeter, 0.18mm 2

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wall thickness) was cut into a cylinder of 20mm of radius and 10mm of height. Some catalyst supports were washed by deionized water and dried at 110℃ for 10h (named “C”), others were washed in ultrasonic bath with nitric acid (20%) for 2h and then washed by deionized water until the pH of the cordierite was neutral and dried at 110℃ for 10h (named “NC”). The weight of each prepared support was about 6g. The catalysts were prepared by incipient wetness impregnation method using the nitrate precursors of Ce (Ce(NO3)3·6H2O) and Mn (Mn(NO3)2 (50% solution)). The metal nitrates were dissolved in deionized water with different molar ratios. After the cordierites were impregnated in the solution, the obtained samples were dried at 110℃ for 10 h and calcined at 400℃ for 3 h subsequently. The prepared catalysts were named “MnxCey/C” where x and y were the molar ratios of Mn and Ce, respectively. The catalysts were prepared by sol-gel method using the same raw materials as the catalysts prepared by incipient wetness impregnation method. The nitrate precursors and citric acid were dissolved in the deionized water to form a mixed solution and the molar ratios of Mn and Ce were 4:1. The solution was heated at 60℃ under continually stirring until it turned to a sol. The supports were immersed in the formed sol and then the blocked channels of the cordierites were purged under a weak air flow. The pretreated samples were dried at 110℃ for 10 h, and then calcined at 400℃ for 3 h subsequently. The catalysts were named “g- Mn4Ce1/C” and “g- Mn4Ce1/NC” when using the “C” and “NC” as the catalyst supports prepared by sol-gel method. The total loading of metals in all the prepared catalysts were 5wt%. 2.2 Catalytic performance evaluation The catalytic activity of the catalysts using for NMHC oxidation in cooking oil fumes was measured in a fixed-bed reactor under atmospheric pressure at 200℃ to 400℃. In order to simulate the real situation, soybean oil was heated at 200℃ to generate cooking oil fumes and the concentration of NMHC from cooking oil fumes was 5000ppm at a flow rate of 200ml/min which was controlled by rotameter. The concentration of NMHC in feed gas and outlet gas was measured using a gas chromatography (GC7900, Techcomp Co., Ltd. China) equipped with two flame ionization detectors (FID), a glass microspheres stainless steel column (0.5m*3mm) and a GDX-502 stainless steel column (5m*3mm) using N2 (99.999%) as the carried gas. 3

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The conversion of NMHC was calculated using the following formula Conversion =

஼೔೙ ି஼೚ೠ೟ ஼೚ೠ೟

× 100%

Where ‫ܥ‬௜௡ (ppm) and ‫ܥ‬௢௨௧ (ppm) was the concentration of NMHC in the feed gas and outlet gas, respectively. 2.3 Catalysts’ characterization The specific surface area, pore volume and average pore diameter of the catalysts were measured by physisorption of N2 using a Micromeritics ASAP 2460 instrument at 77K after the samples were degassed for 2h at 298K. The specific surface area was calculated by the Brunauer-Emmett-Teller (BET) method and the pore size distribution was calculated by the method of Barrett-Joyner-Hallender (BJH). The surface microstructure of the catalysts was obtained from high-resolution images performed on a Hitachi SU8010 type scanning electron microscopy (SEM). Energy dispersive X-ray spectroscopy (EDS) of the samples were tested on the same SEM instrument equipped a HORIBA silicon drift X-ray detector to analyze the element distributions on the surface. In order to improve the quality of the images, the samples were coated with a thin layer of Pt. X-ray diffraction (XRD) was used to analyze the crystalline phases presented in the catalysts. The diffraction patterns were recorded with a Rigaku D/MAX-2200 powder diffractometer using Ni-filtered Cu Kα radiation (λ=0.15406nm) at a scan rate of 5°/min from 2θ equal to 10° up to 90°. The diffractometer was operated at 36KV and 30mA. The JCPDS files were used for the samples’ phase identification. The X-ray photoelectron spectroscopy (XPS) was performed on VG Scientific ESCALab220i-XL electron spectrometer to analyze the chemical composition and functional groups on the surface of the catalysts. The Al Kα radiation as excitation source was operated at 300W. Wide scans were performed from 1100eV to 0eV with a dwell time of 100ms and steps of 1eV. Narrow scans were performed with steps of 0.05eV if the range 20eV with dwell time of 100-400ms.The binding energy (BE) was corrected by the C 1s peak at 284.6eV. 3. Results and discussion 3.1 Catalytic activity of Mn-CeOx/cordierite for NMHC oxidation Figure 1 shows the conversion of NMHC over Mn-CeOx/cordierite with different molar ratios of Mn/Ce at the reaction temperature from 200℃ to 400℃. The experimental results 4

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show that activity of MnxCey/C was observed to follow the sequence below: Mn4Ce1/C > Mn20Ce1/C > Mn/C > Mn16Ce1/C > Mn2Ce1/C> Mn8Ce1/C> Mn12Ce1/C. It can be acquired that with the increased of the Ce content in the catalysts, the activity of the catalysts decreased first and then increased until the molar ratios of Mn/Ce was 4. The activity of the catalyst decreased again when the molar ratio of Mn/Ce was greater than 4 and Mn4Ce1/C exhibited the highest catalytic activity for NMHC oxidation with conversion of 90% at 400℃. The results indicated that adding the appropriate proportion of Ce can obviously improve the activity of catalysts for NMHC oxidation in cooking oil fumes. The possible reason for why the addition of Ce promoting the catalytic activity of catalysts is because of it enhanced not only the oxygen storage and release capacity of the catalysts but also oxygen mobility in the surface and vacancies.

Figure 1. Conversion curves of NMHC over MnxCey/C catalysts with different molar ratios of Mn and Ce. The conversion of NMHC over pure cordierite support and those with Mn4Ce1 catalysts were shown in Figure 2. In the case of C and NC, the conversion of NMHC was quite low even at a very high reaction temperature which indicating that there was no active component on the surface of the cordierites. After loading Mn4Ce1 on the supports, the conversion of NMHC was greatly improved. Meanwhile, different Mn4Ce1 catalysts for NMHC oxidation 5

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were ordered as follow: g-Mn4Ce1/NC > g-Mn4Ce1/C > Mn4Ce1/C.

Figure 2. Conversion curves of NMHC over cordierite support and all Mn4Ce1 catalysts. 3.2 Catalyst characterization Figure 3 presents the XRD patterns of the catalysts with different Mn/Ce molar ratios. From Figure 3a, it is observed that all the samples showed the relatively strong characteristic peaks at 2θ= 10.4°, 18.0°, 21.6°, 26.3°, 28.4°, 33.9° and 54.2° which corresponding to the crystallite structures of cordierite (JCPDS 12-235) because of the high content of cordierite. Meanwhile, the relatively weak diffraction peaks of active species at 2θ=33.0°, 47.4° and 2θ=37.3°, 56.7° ascribed to cubic fluorite-type CeO2 (JCPDS 81-0792) and pyrolusite-type MnO2 (JCPDS 24-735) respectively. According to Figure 3b and Figure 3c, it is clear that the characteristic peak of CeO2 was not obvious as the Mn/Ce molar ratio was higher than 4. It is speculated that the crystal structure of CeO2 had been distorted by the incorporation of the Mn4+ and the high dispersion of CeO2. Compared with Mn/C, no samples showed any diffraction peaks of MnO2 from Figure 3d and Figure 3e which indicated that the Mn4+ had incorporated into the lattice of CeO2 to form a homogeneous Mn-Ce-O solid solution since the ionic radius of Mn4+ 6

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(0.053nm) is smaller than that of the Ce4+ (0.087nm)23-25. It can also be deduced that the crystallinity of the MnO2 became lower and the crystallites size of the MnO2 became smaller after the addition of CeO226-28.

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Figure 3. XRD patterns of the catalysts with different Mn/Ce molar ratios (a: wild angle patterns, b: 2θ equal to 31°-35°, c: 2θ equal to 46°-48°, d: 2θ equal to 36°-39.5°, e: 2θ equal to 8

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56°-57.5°). From Figure 4, it can be seen clearly that the XRD curves of nitic acid treated and Mn4Ce1 supported cordierites has no difference from the virgin one, which illustrated the formation of the Me-Ce-O solid solution and the high dispersion of the active components.

Figure 4. XRD patterns of cordierite support and all the Mn4Ce1 catalysts The SEM images of the catalysts prepared by incipient wetness impregnation method with different Mn/Ce molar ratios are shown in Figure 5. From Figure 5, it can be observed that all the catalysts were covered with a homogeneous layer of active component and the active particles of all the samples have a certain degree of agglomeration which might be caused by the preparation method. As shown in Figure 5a-f, among all the samples, the catalyst with Mn/Ce molar ratio= 4 (Figure 5b) had the most abundant pore structure which leads to a relatively high catalytic activity.

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Figure 5. SEM images of the catalysts prepared by incipient wetness impregnation method with different Mn/Ce molar ratios (a: Mn2Ce1/C, b: Mn4Ce1/C, c: Mn8Ce1/C, d: Mn12Ce1/C, e: Mn16Ce1/C, f: Mn20Ce1/C). Figure 6 shows the SEM images of cordierite support and all Mn4Ce1 catalysts. It was found that the surface of pure cordierite (Figure 6a) was very smooth so that its specific surface area was very low. After treating by nitric acid, there are more pores appeared on the surface of cordierite and made the surface rougher (Figure 6b), which was consistent with BET data from Table 1. The SEM images of catalysts prepared by incipient wetness impregnation method and sol-gel method are shown in Figure 6c and Figure 6d, respectively. As can be seen in the figures, the active phase of those samples made by incipient wetness 10

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was obviously agglomerated while those samples made by sol-gel method had better dispersion, which might due to that the catalysts prepared by sol-gel method have larger specific surface area, smaller total pore volume and smaller average pore size than the catalysts prepared by incipient wetness impregnation method. Figure 6e shows the surface image of the catalyst supported on the cordierite after nitric acid treatment by sol-gel method. Compared with other samples, its active phase had the best dispersion and pore structure which is in agreement with BET data.

Figure 6. SEM images of the cordierite support and all Mn4Ce1 catalysts (a: C, b: NC, c: Mn4Ce1/C, d: g- Mn4Ce1/C, e: g- Mn4Ce1/NC). In order to analyze the distribution of catalysts’ surface elements, EDS energy spectrum 11

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was carried out. As shown in Figure 7, some elements composition such as Si, Al and Mg accounted for a large proportion attributed to the components of cordierite and the Mn/Ce molar ratios were similar to the theoretical value which indicated that the active phase had been well attached onto the surface of cordierite. The EDS patterns of catalysts prepared by sol-gel method and incipient wetness impregnation method are shown in Figure 7a and Figure 7b, respectively. It is clearly that the active phase of catalyst prepared by sol-gel method had better dispersion and those prepared by incipient wetness impregnation method was obviously agglomerated as seen in EDS-mapping images from Figure 7. From the catalytic activity and EDS-mapping results, it can be speculated that better dispersion of catalysts’ active component is one of the reasons for the good catalytic performance.

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Figure 7. EDS patterns of catalysts prepared by sol-gel method and incipient wetness impregnation method (a: g- Mn4Ce1/C, b: Mn4Ce1/C). The specific surface area (SBET), total pore volume (DV) and average pore size (DP) of 13

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cordierite support and all the Mn4Ce1 catalysts were shown in Table 1. It is clearly that the specific surface area and total pore volume of the cordierite increased after nitric acid treatment, but the average pore size showed the opposite effect. That might because the cordierite was corroded by nitric acid on the surface and generated many little pores. The specific surface area and total pore volume of all the Mn4Ce1 catalysts were much higher than the cordierite. Compared Mn4Ce1/C with g-Mn4Ce1/C in Table 1, it can be seen that the catalysts prepared by sol-gel method have larger specific surface area, smaller total pore volume and smaller average pore size than those prepared by incipient wetness impregnation method, which indicated that the catalysts can obtain richer pore structure through sol-gel method. Among all the catalysts, g-Mn4Ce1/NC has largest specific surface area (15.0639 m2/g) and best pore structure which resulted in a high catalytic activity in the oxidation of NMHC in cooking oil fumes, as shown in Figure 2. Table 1 Textural properties of the catalyst supports and Mn4Ce1 catalysts. Materials

SBET a (m2/g)

DV b (10-8m3/g)

DP c (nm)

C

1.76

0.33

10.2

NC

3.02

0.36

8.1

Mn4Ce1/C

8.18

2.95

14.9

g-Mn4Ce1/C

12.14

2.58

7.1

g-Mn4Ce1/NC

15.06

2.95

8.2

a

BET specific surface area.

b

BJH desorption cumulative volume of pores.

c

BJH desorption average pore width. Figure 8 shows the XPS spectra for Mn 2p3/2, Ce 3d and O 1s of various

Mn-Ce/cordierite catalysts. The surface element compositions calculated from the ratios of peak areas of XPS spectra were displayed in Table 2. From Figure 8a, the spectra for Mn 2p3/2 could be divided into two components at BE=641.6eV and BE=642.9eV attributed to Mn3+ and Mn4+29-31, respectively. Combined with Table 2, it is clearly that the surface Mn4+/Mn3+ molar ratios was greatly affected by the addition of Ce. The Mn4Ce1/C had the highest surface Mn4+/Mn3+ molar ratios (1.99) whereas 14

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the Mn2Ce1/C and Mn8Ce1/C had relatively low surface Mn4+/Mn3+ molar ratios (1.07 and 1.33) which indicated that the Mn4Ce1/C had relatively high average manganese oxidation state. Generally, the catalyst with higher Mn4+/Mn3+ molar ratios on the surface has more adsorbed oxygen species as active oxygen because of electro-neutrality32, 33 which will be demonstrated by the XPS spectra for O 1s. Figure 8b shows the XPS spectra for Ce 3d which exhibited eight characteristic peaks assignable to the Ce3+ (BE=884.7eV and 902.0eV) and Ce4+ (BE=882.5eV, 888.1eV, 898.3eV, 900.7eV, 906.6eV and 916.7eV)21. As summarized in Table 2, the molar ratios of Ce4+/Ce3+ was approximately 6.21 for Mn2Ce1/C, 7.39 for Mn4Ce1/C and 3.80 for Mn8Ce1/C according to the measurement of the peak areas. The result shows that the oxidation state of Ce was predominantly tetravalent for all the catalysts. Besides, higher surface Ce4+/Ce3+ molar ratio may result in greater oxygen storage and release capacity, and can easily generate labile oxygen vacancies and highly mobile oxygen therefore have better catalytic oxidation performance21, 22, 34, 35. In Figure 8c, the O 1s XPS spectra of all the samples can be deconvoluted to three characteristic peaks at BE=529.6eV, 531.2eV and 532.3eV corresponding to the lattice oxygen (O2-, denoted as Olatt), surface adsorbed oxygen species (O2-, O22- or O-, denoted as Oads) and hydroxyl or adsorbed water36-38. It is believed that Oads species has more activity than Olatt in the oxidation reactions due to higher oxygen mobility36, 39. So the ratio of Oads/Olatt can represent the activity of the catalyst to some extent. In Table 2, the ratio of Oads/Olatt in Mn4Ce1/C (1.12) was clearly higher than that in Mn2Ce1/C and Mn8Ce1/C (0.48 and 0.39) which is consistent with the XPS spectra for Mn 2p3/2 and the sequence of catalysts’ activity. Table 2 Surface element compositions of the catalysts with different Mn/Ce molar ratios. Materials

Mn4+/Mn3+

Ce4+/Ce3+

Oads/Olatt

Mn2Ce1/C

1.07

6.21

0.48

Mn4Ce1/C

1.99

7.39

1.12

Mn8Ce1/C

1.33

3.80

0.39

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Figure 8. XPS spectra of the catalysts with different Mn/Ce molar ratios for a: Mn 2p3/2, b: Ce 3d, c: O 1s. 4. Conclusions 16

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In summary, Catalysts with different molar ratios of Mn/Ce and Mn4Ce1 catalysts prepared by different methods were used for NMHC oxidation in COFs. The Mn4Ce1 catalyst supported on the cordierite after nitric acid treatment using a sol-gel method presented better catalytic performance than Mn4Ce1/C attributed to higher BET specific surface area, more abundant pore structure and better dispersion of catalysts’ active component. Meanwhile, the Mn4Ce1/C exhibited higher catalytic activity than the catalysts with other molar ratios of Mn/Ce showing the 90% conversion of NMHC at 400℃ due to more adsorbed oxygen species and higher ratio of Ce4+/Ce3+. Acknowledgements This research was supported by program for New Century Excellent Talents in University (NCET-12-0776). References (1) Ou, J.; Guo, H.; Zheng, J.; Cheung, K.; Louie, P. K. K.; Ling, Z.; Wang, D., Concentrations and sources of non-methane hydrocarbons (NMHCs) from 2005 to 2013 in Hong Kong: A multi-year real-time data analysis. Atmos. Environ. 2015, 103, 196-206. (2) Barletta, B.; Meinardi, S.; Rowland, F. S.; Chan, C. Y.; Wang, X. M.; Zou, S. C.; Chan, L. Y.; Blake, D. R., Volatile organic compounds in 43 Chinese cities. Atmos. Environ. 2005, 39, 5979-5990. (3) Barletta, B.; Meinardi, S.; Simpson, I. J.; Zou, S. C.; Rowland, F. S.; Blake, D. R., Ambient mixing ratios of nonmethane hydrocarbons (NMHCs) in two major urban centers of the Pearl River Delta (PRD) region: Guangzhou and Dongguan. Atmos. Environ. 2008, 42, 4393-4408. (4) Wang, J.-l.; Zhong, J.-b.; Gong, M.-c.; Liu, Z.-m.; Zhao, M.; Chen, Y.-q., Remove cooking fume using catalytic combustion over Pt/La-Al2O3. J. Environ. Sci. 2007, 19, 644-646. (5) Kabir, E.; Kim, K. H., An investigation on hazardous and odorous pollutant emission during cooking activities. J Hazard Mater 2011, 188, 443-54. (6) Wang, J.; Liao, C.; Chen, Y.; Cao, H.; Liu, Z.; Gong, M.; Chen, Y., Low-Temperature Catalytic Combustion of Cooking Fume over Pt/Y-Al2O3/Ce0.5-xZr0.5-xMn2xO2 Monolithic Catalyst. Chin. J. Catal. 2010, 31, 404-408. (7) Cheng, S.; Wang, G.; Lang, J.; Wen, W.; Wang, X.; Yao, S., Characterization of volatile organic compounds from different cooking emissions. Atmos. Environ. 2016, 145, 299-307. (8) Liakakou, E.; Bonsang, B.; Williams, J.; Kalivitis, N.; Kanakidou, M.; Mihalopoulos, N., C2–C8 NMHCs over the Eastern Mediterranean: Seasonal variation and impact on regional oxidation chemistry. Atmos. Environ. 2009, 43, 5611-5621. (9) Platt, S. M.; El Haddad, I.; Zardini, A. A.; Clairotte, M.; Astorga, C.; Wolf, R.; Slowik, J. G.; Temime-Roussel, B.; Marchand, N.; Jezek, I.; Drinovec, L.; Mocnik, G.; Mohler, O.; Richter, R.; Barmet, P.; Bianchi, F.; Baltensperger, U.; Prevot, A. S. H., Secondary organic aerosol formation from gasoline vehicle emissions in a new mobile environmental reaction chamber. Atmos. Chem. Phys. 2013, 13, 9141-9158. (10) Ziemann, P. J.; Atkinson, R., Kinetics, products, and mechanisms of secondary organic aerosol formation. Chem. Soc. Rev. 2012, 41, 6582-6605. (11) Sun, S.; Schiller, J. H.; Gazdar, A. F., Lung cancer in never smokers - a different disease. Nat. Rev. Cancer 17

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2007, 7, 778-790. (12) Mu, L. N.; Liu, L.; Niu, R. G.; Zhao, B. X.; Shi, J. P.; Li, Y. L.; Swanson, M.; Scheider, W.; Su, J.; Chang, S. C.; Yu, S. Z.; Zhang, Z. F., Indoor air pollution and risk of lung cancer among Chinese female non-smokers. Cancer Cause Control 2013, 24, 439-450. (13) Pandit, G. G.; Sahu, S. K.; Puranik, V. D., Distribution and source apportionment of atmospheric non-methane hydrocarbons in Mumbai, India. Atmos. Pollut. Res. 2011, 2, 231-236. (14) Li, S. D.; Wang, H. S.; Li, W. M.; Wu, X. F.; Tang, W. X.; Chen, Y. F., Effect of Cu substitution on promoted benzene oxidation over porous CuCo-based catalysts derived from layered double hydroxide with resistance of water vapor. Appl. Catal., B: Environ. 2015, 166, 260-269. (15) Takeuchi, M.; Hidaka, M.; Anpo, M., Efficient removal of toluene and benzene in gas phase by the TiO2/Y-zeolite hybrid photocatalyst. J. Hazard. Mater. 2012, 237, 133-139. (16) Anil, C.; Madras, G., Kinetics of CO oxidation over Cu doped Mn3O4. J. Mol. Catal. A: Chem. 2016, 424, 106-114. (17) Li, D.; Shen, G.; Tang, W.; Liu, H.; Chen, Y., Large-scale synthesis of hierarchical MnO2 for benzene catalytic oxidation. Particuology 2014, 14, 71-75. (18) Zeng, J. L.; Liu, X. L.; Wan, J.; Lv, H. L.; Zhu, T. Y., Catalytic oxidation of benzene over MnOx/TiO2 catalysts and the mechanism study. J. Mol. Catal. A: Chem. 2015, 408, 221-227. (19) Yodsa-nga, A.; Millanar, J. M.; Neramittagapong, A.; Khemthong, P.; Wantala, K., Effect of manganese oxidative species in as-synthesized K-OMS 2 on the oxidation of benzene. Surf. Coat. Technol. 2015, 271, 217-224. (20) Ke, Y.; Lai, S.-Y., Comparison of the catalytic benzene oxidation activity of mesoporous ceria prepared via hard-template and soft-template. Microporous Mesoporous Mater. 2014, 198, 256-262. (21) Shen, B. X.; Wang, F. M.; Liu, T., Homogeneous MnOx-CeO2 pellets prepared by a one-step hydrolysis process for low-temperature NH3-SCR. Powder Technol. 2014, 253, 152-157. (22) Qi, G. S.; Yang, R. T.; Chang, R., MnOx-CeO2 mixed oxides prepared by co-precipitation for selective catalytic reduction of NO with NH3 at low temperatures. Appl. Catal., B: Environ. 2004, 51, 93-106. (23) Lu, H.; Zhou, Y.; Huang, H.; Zhang, B.; Chen, Y., In-situ synthesis of monolithic Cu-Mn-Ce/cordierite catalysts towards VOCs combustion. J. Rare Earths 2011, 29, 855-860. (24) She, Y. S.; Zheng, Q.; Li, L.; Zhan, Y. Y.; Chen, C. Q.; Zheng, Y. H.; Lin, X. Y., Rare earth oxide modified CuO/CeO2 catalysts for the water-gas shift reaction. Int. J. Hydrogen Energy 2009, 34, 8929-8936. (25) Chen, H.; Sayari, A.; Adnot, A.; Larachi, F., Composition-activity effects of Mn-Ce-O composites on phenol catalytic wet oxidation. Appl. Catal., B: Environ. 2001, 32, 195-204. (26) Li, T. Y.; Chiang, S. J.; Liaw, B. J.; Chen, Y. Z., Catalytic oxidation of benzene over CuO/Ce1-xMnxO2 catalysts. Appl. Catal., B: Environ. 2011, 103, 143-148. (27) Yang, P.; Li, J.; Zuo, S., Promoting oxidative activity and stability of CeO 2 addition on the MnO x modified kaolin-based catalysts for catalytic combustion of benzene. Chem. Eng. Sci. 2017, 162, 218-226. (28) Picasso, G.; Gutierrez, A.; Pina, M. P.; Herguido, J., Preparation and characterization of Ce-Zr and Ce-Mn based oxides for n-hexane combustion: Application to catalytic membrane reactors. Chem. Eng. J. 2007, 126, 119-130. (29) Wang, X. Y.; Kang, Q.; Li, D., Catalytic combustion of chlorobenzene over MnOx-CeO2 mixed oxide catalysts. Appl. Catal., B: Environ. 2009, 86, 166-175. (30) Zhang, Y. G.; Qin, Z. F.; Wang, G. F.; Zhu, H. Q.; Dong, M.; Li, S. N.; Wu, Z. W.; Li, Z. K.; Wu, Z. H.; Zhang, J.; Hu, T. D.; Fan, W. B.; Wang, J. G., Catalytic performance of MnOx-NiO composite oxide in lean methane combustion at low temperature. Appl. Catal., B: Environ. 2013, 129, 172-181. (31) Ye, Q.; Zhao, J. S.; Huo, F. F.; Wang, D.; Cheng, S. Y.; Kang, T. F.; Dai, H. X., Nanosized Au supported on 18

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