Interfaces in MOF-Derived CeO 2 –MnO X Composites as High-Activity Catalysts for Toluene Oxidation: Monolayer Dispersion Threshold

: A series of CeO 2 –MnO X catalysts with di ﬀ erent Ce contents was prepared using Mn–BTC MOF as a sacriﬁcial template for toluene oxidation. Interestingly, the performance of CeO 2 –MnO X increased rapidly only when the Ce content lower than 5%. The 1%-, 3%- and 10%-Ce-content samples exhibited the T 90 value of 325 ◦ C, 291 ◦ C and 277 ◦ C, respectively. XRD shows that the catalyst phase changes signiﬁcantly before (Mn 3 O 4 only) and after (Mn 2 O 3 , Mn 3 O 4 and CeO 2 ) 3% Ce loading. All other results indicated that the Ce–Mn interface properties of di ﬀ erent Ce content composite oxides was quite distinguishable in terms of removal and energy e ﬃ ciency. XRD and XPS results further showed that there a Ce monolayer dispersion threshold existed on the interface of MnO X (3.2 wt%, conﬁrmed by XPS), which caused the di ﬀ erence in performance increment. The dispersed Ce could be divided into a monolayer dispersion state (1–3%) and a crystalline phase state ( > 3%), according to the existence form, which corresponded to the signiﬁcant and minor enhancements of toluene conversion rate. Importantly, the Ce in monolayer dispersion state obviously improved the redox properties of catalysts interface, while the Ce in crystal state not. The interfaces with monolayer dispersion Ce result in more abundant metal ion states, oxygen vacancies, better electron transfer performance and catalytic activity.


Introduction
Volatile organic compounds (VOCs) are common harmful gases that play a key role in the conversion of other atmospheric pollutants, such as fine particles (PM 2.5 ) and ground-level ozone (O 3 ) [1,2], thus making a significant impact on atmospheric environment and human health. Reducing the emission of VOCs is important in sustainable development [3,4]. Catalytic oxidation-one of the current recycling and destruction technologies-has been thought to be an effective measure to control VOCs in industries [5]. High efficiency, light secondary pollution, and low risks are the prerequisites for a generalized application. Therefore, a variety of metal oxides (MO X , M = Ce, Cr, Fe, Co, Cu, Mn, etc.) are considered as economical options for the compositions of the catalysts. All the above metal oxides are considered in the order of effectiveness for VOCs. Compared to others, cerium and Mn-BTC). One Mn 2+ and six oxygen atoms form an octahedron structure. Moreover, the octahedrons were connected to each other to form a channel-like three-dimensional network. The thermal stability of Mn-BTC was examined by thermogravimetric analysis (TGA) in air, which was showed in Figure S1b. In the range of 50-200 • C, a curve weight loss platform that could be attributed to the loss of absorbed water was detected, followed by MOF decomposition over 300 • C. The total weight loss of Mn-BTC was 70.1%, which was consistent with the theoretical value of 71.5% calculating the quantity of water and organic framework. It could be observed in Figure S1c that the sample showed a rod-like shape with smooth surface.

Optimization of Calcination Temperature
As a synthetic template, it is vital to determine the appropriate calcination temperature of Mn-BTC. This study is meaningful not only in ensuring the complete decomposition of MOF and the formation of pure oxides, but also in avoiding particle aggregation under high calcination temperature. According to the TG results, Mn-BTCs were further calcinated at 300 • C, 400 • C, 450 • C, 500 • C and 600 • C to obtain several manganese oxides, which were denoted as Mn 3 O 4 -T, respectively.
The phase and crystal structure of the calcinated Mn 3 O 4 -T were examined by XRD, as shown in Figure S2a and Table 1. The patterns show that all diffraction peaks of the samples could be assigned to Mn 3 O 4 (JCPDS 24-0734). As the calcination temperature increasing, the widths of peaks get narrower while the intensities become stronger, suggesting the high crystallinity of samples at a high temperature. Moreover, the average crystallite size of Mn 3 O 4 -T increased rapidly, indicating that excessively high temperature would lead to sintering of Mn 3 O 4 nanoparticles. This is obviously not conducive in improving catalytic activity. Moreover, the elemental analysis of Mn 3 O 4 -300 (Table S1) reveals that only 1.73% organic portions remain, indicating the complete decomposition of the organic-frameworks during calcination process.

Samples
Average Crystallite Size a (nm) S BET (m 2 g −1 ) Total Pore Volume (cm 3  The N 2 adsorption/desorption isotherms of Mn 3 O 4 -T are shown in Figure S2b. All samples showed well-developed mesoporous structure and features of the type II isotherms with hysteresis loops. The values of specific surface area (S BET , confirmed by BET) are listed in Table 1. The proper heat-treatment was a key factor for the S BET and pore volume increase. Mn 3 O 4 -300 exhibits the highest surface area, 19.4 m 2 g −1 .
The morphology and nanostructure of the Mn 3 O 4 -T samples were investigated by SEM and HRTEM. The results are showed in Figure 1. The characterization of Mn 3 O 4 calcinated at other temperatures can be found in Figure S4. It can be seen that the Mn 3 O 4 -300 remains a rod-like shape, even after heat treatment. However, the surface of the sample becomes rougher, which can be attributed to the formation of mesoporous caused by the loss of the organic portions. TEM reveals that nanorod is composed of numerous nanoparticles. The connection between Mn 3 O 4 particles kept multiple active interfaces in the catalyst [28]. Based on the above observations, a possible procedure for the calcination was then proposed. During the calcination process, the organic ligands decomposed into CO2(g) and H2O(g), which spilled out from the framework afterward, leading to the formation of interior void space. Meanwhile, the metal ions Mn 2+ oxidized into Mn3O4 nanoparticles. Moreover, all the results show that the complete decomposition of Mn-BTC could be obtained under calcination temperature of 300 °C, resulting in Mn3O4-300 sample with better features in catalysis. Therefore, we take 300 °C as the appropriate calcination temperature in the follow-up experiments.

Catalytic Tests
Using Mn-BTC as templates, a series of wCeO2-MnOX-300 with different Ce contents (or wCeO2-MnOX, for short) were successfully synthesized and used for toluene oxidation. Resulted of toluene TPO were showed in Figure 2. Obviously, the catalytic activities and Ce contents were directly related. With increasing Ce contents, wCeO2-MnOX catalysts exhibited better catalytic performance. Interestingly, when the Ce contents reached 3%, the samples no longer perform a significant increased activity. It suggests that when the amount of Ce reached a limit, the rest of the Ce cations spread on the surface of MnOX, leading to no improvement of catalytic activity. Moreover, 100% conversion of toluene could be obtained at a temperature of 300 °C for wCeO2-MnOX (w ≥ 3%) catalysts. The results of the catalyst stability are shown in Figure S3. The activity of the catalysts did not decrease significantly after 30 h of continuous use.  Based on the above observations, a possible procedure for the calcination was then proposed. During the calcination process, the organic ligands decomposed into CO 2 (g) and H 2 O(g), which spilled out from the framework afterward, leading to the formation of interior void space. Meanwhile, the metal ions Mn 2+ oxidized into Mn 3 O 4 nanoparticles. Moreover, all the results show that the complete decomposition of Mn-BTC could be obtained under calcination temperature of 300 • C, resulting in Mn 3 O 4 -300 sample with better features in catalysis. Therefore, we take 300 • C as the appropriate calcination temperature in the follow-up experiments.

Catalytic Tests
Using Mn-BTC as templates, a series of wCeO 2 -MnO X -300 with different Ce contents (or wCeO 2 -MnO X , for short) were successfully synthesized and used for toluene oxidation. Resulted of toluene TPO were showed in Figure 2. Obviously, the catalytic activities and Ce contents were directly related. With increasing Ce contents, wCeO 2 -MnO X catalysts exhibited better catalytic performance. Interestingly, when the Ce contents reached 3%, the samples no longer perform a significant increased activity. It suggests that when the amount of Ce reached a limit, the rest of the Ce cations spread on the surface of MnO X , leading to no improvement of catalytic activity. Moreover, 100% conversion of toluene could be obtained at a temperature of 300 • C for wCeO 2 -MnO X (w ≥ 3%) catalysts. The results of the catalyst stability are shown in Figure S3. The activity of the catalysts did not decrease significantly after 30 h of continuous use. Based on the above observations, a possible procedure for the calcination was then proposed. During the calcination process, the organic ligands decomposed into CO2(g) and H2O(g), which spilled out from the framework afterward, leading to the formation of interior void space. Meanwhile, the metal ions Mn 2+ oxidized into Mn3O4 nanoparticles. Moreover, all the results show that the complete decomposition of Mn-BTC could be obtained under calcination temperature of 300 °C, resulting in Mn3O4-300 sample with better features in catalysis. Therefore, we take 300 °C as the appropriate calcination temperature in the follow-up experiments.

Catalytic Tests
Using Mn-BTC as templates, a series of wCeO2-MnOX-300 with different Ce contents (or wCeO2-MnOX, for short) were successfully synthesized and used for toluene oxidation. Resulted of toluene TPO were showed in Figure 2. Obviously, the catalytic activities and Ce contents were directly related. With increasing Ce contents, wCeO2-MnOX catalysts exhibited better catalytic performance. Interestingly, when the Ce contents reached 3%, the samples no longer perform a significant increased activity. It suggests that when the amount of Ce reached a limit, the rest of the Ce cations spread on the surface of MnOX, leading to no improvement of catalytic activity. Moreover, 100% conversion of toluene could be obtained at a temperature of 300 °C for wCeO2-MnOX (w ≥ 3%) catalysts. The results of the catalyst stability are shown in Figure S3. The activity of the catalysts did not decrease significantly after 30 h of continuous use.

XRD and BET Analysis
The performance of catalysts is directly affected by their structures. Figure 3 presents the results of XRD and N 2 sorption isotherms of wCeO 2 -MnO X . Moreover, the textural parameters of wCeO 2 -MnO X are also summarized in Table 2. The XRD patterns show that the diffraction peaks which ascribed to Mn 3 O 4 (JCPDS 24-0734) could be found in all samples, whereas the peaks become broader with the increasing Ce content. This may be due to the entrance of Ce n+ , which was consistent with the increasing lattice constant ( Table 2). It suggests that Me-Ce solid solution formed at the particle interfaces and expanded the size of lattice [29][30][31]. The phase structure of Mn-BTC nanorods had a rich and uniform pore structure, and long-term immersion ensured that Ce ions enter these pore channels. A small portion of Ce entered the Mn-MOF and formed a Ce-Mn solid solution (enters the crystal lattice of MnO X ) during the subsequent pyrolysis. Most of the remaining CeO 2 and MnO X growth was spatially staggered. This made the Ce ions in the template have a separation effect on MnO X , which in turn provided the possibility to increase the specific surface area. From the results of BET analysis, the average crystallite size of samples did decrease with increasing Ce content, revealing that Ce cations effectively separated the MnO X and led to bigger specific surface area ( Table 2). It is worth noting that the characteristic reflections of Mn 2 O 3 (JCPDS 24-0508) and CeO 2 (JCPDS 34-0394) could also be found in wCeO 2 -MnO X (w ≥ 3%) and wCeO 2 -MnO X (w ≥ 5%), respectively. Obviously, Ce does not crystallize in wCeO 2 -MnO X (w ≤ 3%) but bind to the surface of MnO X in a highly dispersed state. The results prove that there were indeed two states of interface Ce, monolayer dispersion state and crystalline state. The existence form of Ce changes with the increase of load. It can be concluded that the threshold effect most likely to be responsible for these results [19]. To be specific, when the amount of dispersed Ce was below monolayer dispersion threshold, Ce ions interacted with the reactive site on MnO X surface to form a single layer of surface compound that scattered over the surface; when the amount of dispersive Ce exceeded the monolayer dispersion threshold, superfluous Ce existed as CeO 2 on the surface of catalysts. For the reason that Ce oxides generation and Mn-MOF decomposition proceed simultaneously, Ce cations could be dispersed on the surface of fine and newly formed MnO X nanoparticles, preventing aggregation of the particles and resulting in the increase of surface-specific area [17]. The turning of existence form of Ce shown by XRD was highly consistent with the toluene catalytic activity of wCeO 2 -MnO X . Obviously, the state of Ce was directly related to the catalytic activity of the system. To further prove the above deductions, more characterizations were used to verify the results.

XRD and BET Analysis
The performance of catalysts is directly affected by their structures. Figure 3 presents the results of XRD and N2 sorption isotherms of wCeO2-MnOX. Moreover, the textural parameters of wCeO2-MnOX are also summarized in Table 2. The XRD patterns show that the diffraction peaks which ascribed to Mn3O4 (JCPDS 24-0734) could be found in all samples, whereas the peaks become broader with the increasing Ce content. This may be due to the entrance of Ce n+ , which was consistent with the increasing lattice constant ( Table 2). It suggests that Me-Ce solid solution formed at the particle interfaces and expanded the size of lattice [29][30][31]. The phase structure of Mn-BTC nanorods had a rich and uniform pore structure, and long-term immersion ensured that Ce ions enter these pore channels. A small portion of Ce entered the Mn-MOF and formed a Ce-Mn solid solution (enters the crystal lattice of MnOX) during the subsequent pyrolysis. Most of the remaining CeO2 and MnOX growth was spatially staggered. This made the Ce ions in the template have a separation effect on MnOX, which in turn provided the possibility to increase the specific surface area. From the results of BET analysis, the average crystallite size of samples did decrease with increasing Ce content, revealing that Ce cations effectively separated the MnOX and led to bigger specific surface area ( Table  2). It is worth noting that the characteristic reflections of Mn2O3 (JCPDS 24-0508) and CeO2 (JCPDS 34-0394) could also be found in wCeO2-MnOX (w ≥ 3%) and wCeO2-MnOX (w ≥ 5%), respectively. Obviously, Ce does not crystallize in wCeO2-MnOX (w ≤ 3%) but bind to the surface of MnOX in a highly dispersed state. The results prove that there were indeed two states of interface Ce, monolayer dispersion state and crystalline state. The existence form of Ce changes with the increase of load. It can be concluded that the threshold effect most likely to be responsible for these results [19]. To be specific, when the amount of dispersed Ce was below monolayer dispersion threshold, Ce ions interacted with the reactive site on MnOX surface to form a single layer of surface compound that scattered over the surface; when the amount of dispersive Ce exceeded the monolayer dispersion threshold, superfluous Ce existed as CeO2 on the surface of catalysts. For the reason that Ce oxides generation and Mn-MOF decomposition proceed simultaneously, Ce cations could be dispersed on the surface of fine and newly formed MnOX nanoparticles, preventing aggregation of the particles and resulting in the increase of surface-specific area [17]. The turning of existence form of Ce shown by XRD was highly consistent with the toluene catalytic activity of wCeO2-MnOX. Obviously, the state of Ce was directly related to the catalytic activity of the system. To further prove the above deductions, more characterizations were used to verify the results.

SEM and TEM Analysis
The morphology and crystalline plane are examined by SEM and HRTEM. From Figure 4, it can be observed that the obtained wCeO 2 -MnO X catalysts still remain the original rod shape, though a small fraction of the samples were cracked to pieces. The fine particles that make up the nanorods are highly crystallized and tightly connected. Crystal planes of Mn 3 O 4 are easily found in all samples, while interlayer spacings of Mn 2 O 3 and CeO 2 can only be observed in wCeO 2 -MnO X (w ≥ 3%) and wCeO 2 -MnO X (w ≥ 5%), respectively. The results are highly consistent with the XRD patterns. To confirm the elements distribution of wCeO 2 -MnO X , the results of EDS elemental mapping are given in Figure 5. The uniform distributions of the Ce, Mn and O elements are conducive to form highly active Ce-Mn interfaces, and offer the further possibility of improvement in toluene oxidation.

Raman Spectra Analysis
The Raman spectra of wCeO 2 -MnO X are given in Figure 6. The main band centered at 645 cm −1 is detected in all catalysts, which is generally attached to the vibration of Mn-O-Mn in Mn 3 O 4 [32]. Furthermore, the band over 645 cm −1 can be observed visible increase in bandwidth and band center blue-shifts, which can be explained by the defects formed in Mn 3 O 4 and the smaller particle size of crystals. On one hand, the incorporation of cerium changes the atomic coordination of manganese and induces more defects in crystal. On the other hand, the reduction of crystal size caused the change of phonon confinement and inhomogeneous strain broadening [11]. In addition, characteristic Raman band of Mn 2 O 3 (340 cm −1 ) [33] and CeO 2 (460 cm −1 ) [30,34] can also be found in wCeO 2 -MnO X (w ≥ 3%) and wCeO 2 -MnO X (w ≥ 5%), respectively, which agrees well with the XRD result. The existence of Mn 2 O 3 is presumed to be attributed to the interaction between Ce and Mn which induced the valence of Mn 3 O 4 [35,36], and the presence of CeO 2 demonstrates that the excess Ce is present as crystals on the catalyst surface. In general, the Raman spectra further prove the fact that Ce not only dispersed homogeneously as surface compound and oxides on the surface of MnO X, but also changed the interface properties of catalysts, such as oxygen vacancy, metal valence state, etc. Moreover, this change is mainly caused by the Ce below the monolayer-dispersed threshold.

X-ray Photoelectron Spectroscopy (XPS) Analysis
X-ray photoelectron spectroscopy (XPS) is a common means in analyzing the surface elemental compositions and oxidation states of catalysts [37]. Moreover, the XPS extrapolation method has been developed to quantify the monolayer dispersion threshold in oxide or salt catalyst systems [38][39][40].
To determine the monolayer dispersion threshold, XPS characterizations for wCeO 2 -MnO X (w = 1-30%) were conducted. The peak areas of Ce 3d and Mn 2p are presented (I Ce 3d and I Mn 2p , respectively), and the mass fractions of Ce (w = 1-3%) are converted into corresponding CeO 2 loading (g CeO 2 /g MnO X ). The relationship between ratios of I Ce 3d /I Mn 2p and Ce loading contents are showed in Figure 7. The fitting curve clearly shows two trends. In the lower Ce loading range (1-3%), the slope of Line 1 is very big. At this stage, the Ce is mainly dispersed in the monolayer state on the catalysts surface and interacts with MnO X to form a high dispersed Ce-Mn surface compound [41]. When the Ce loading exceeds a certain value, the line 2 is obviously flattening out. It reveals the existence of Ce veers away from monolayer dispersion state and turn to the crystalline phase. At the intersection of extrapolation line 1 and extrapolation line 2 (red line in Figure 7), the value of x is 0.08 g CeO 2 /g MnO X , which converted to the mass fraction of Ce is 3.2%. The intersection is the demarcation of the two forms of Ce species on the surface of the MnO X carrier, and that is the monolayer dispersion threshold of the system [38].

Raman Spectra Analysis
The Raman spectra of wCeO2-MnOX are given in Figure 6. The main band centered at 645 cm −1 is detected in all catalysts, which is generally attached to the vibration of Mn-O-Mn in Mn3O4 [32]. Furthermore, the band over 645 cm −1 can be observed visible increase in bandwidth and band center blue-shifts, which can be explained by the defects formed in Mn3O4 and the smaller particle size of crystals. On one hand, the incorporation of cerium changes the atomic coordination of manganese and induces more defects in crystal. On the other hand, the reduction of crystal size caused the change of phonon confinement and inhomogeneous strain broadening [11]. In addition, characteristic Raman band of Mn2O3 (340 cm −1 ) [33] and CeO2 (460 cm −1 ) [30,34] can also be found in wCeO2-MnOX (w ≥ 3%) and wCeO2-MnOX (w ≥ 5%), respectively, which agrees well with the XRD result. The existence of Mn2O3 is presumed to be attributed to the interaction between Ce and Mn which induced the valence of Mn3O4 [35,36], and the presence of CeO2 demonstrates that the excess Ce is present as crystals on the catalyst surface. In general, the Raman spectra further prove the fact that Ce not only dispersed homogeneously as surface compound and oxides on the surface of MnOX, but also changed the interface properties of catalysts, such as oxygen vacancy, metal valence state, etc. Moreover, this change is mainly caused by the Ce below the monolayer-dispersed threshold.

X-Ray Photoelectron Spectroscopy (XPS) Analysis
X-ray photoelectron spectroscopy (XPS) is a common means in analyzing the surface elemental compositions and oxidation states of catalysts [37]. Moreover, the XPS extrapolation method has been developed to quantify the monolayer dispersion threshold in oxide or salt catalyst systems [38][39][40].

Raman Spectra Analysis
The Raman spectra of wCeO2-MnOX are given in Figure 6. The main band centered at 645 cm −1 is detected in all catalysts, which is generally attached to the vibration of Mn-O-Mn in Mn3O4 [32]. Furthermore, the band over 645 cm −1 can be observed visible increase in bandwidth and band center blue-shifts, which can be explained by the defects formed in Mn3O4 and the smaller particle size of crystals. On one hand, the incorporation of cerium changes the atomic coordination of manganese and induces more defects in crystal. On the other hand, the reduction of crystal size caused the change of phonon confinement and inhomogeneous strain broadening [11]. In addition, characteristic Raman band of Mn2O3 (340 cm −1 ) [33] and CeO2 (460 cm −1 ) [30,34] can also be found in wCeO2-MnOX (w ≥ 3%) and wCeO2-MnOX (w ≥ 5%), respectively, which agrees well with the XRD result. The existence of Mn2O3 is presumed to be attributed to the interaction between Ce and Mn which induced the valence of Mn3O4 [35,36], and the presence of CeO2 demonstrates that the excess Ce is present as crystals on the catalyst surface. In general, the Raman spectra further prove the fact that Ce not only dispersed homogeneously as surface compound and oxides on the surface of MnOX, but also changed the interface properties of catalysts, such as oxygen vacancy, metal valence state, etc. Moreover, this change is mainly caused by the Ce below the monolayer-dispersed threshold.

X-Ray Photoelectron Spectroscopy (XPS) Analysis
X-ray photoelectron spectroscopy (XPS) is a common means in analyzing the surface elemental compositions and oxidation states of catalysts [37]. Moreover, the XPS extrapolation method has been developed to quantify the monolayer dispersion threshold in oxide or salt catalyst systems [38][39][40].
To determine the monolayer dispersion threshold, XPS characterizations for wCeO2-MnOX (w = 1%-30%) were conducted. The peak areas of Ce 3d and Mn 2p are presented (ICe 3d and IMn 2p, respectively), and the mass fractions of Ce (w = 1%-3%) are converted into corresponding CeO2 loading (g CeO2/g MnOX). The relationship between ratios of ICe 3d/IMn 2p and Ce loading contents are showed in Figure  7. The fitting curve clearly shows two trends. In the lower Ce loading range (1%-3%), the slope of Line 1 is very big. At this stage, the Ce is mainly dispersed in the monolayer state on the catalysts surface and interacts with MnOX to form a high dispersed Ce-Mn surface compound [41]. When the Ce loading exceeds a certain value, the line 2 is obviously flattening out. It reveals the existence of Ce veers away from monolayer dispersion state and turn to the crystalline phase. At the intersection of extrapolation line 1 and extrapolation line 2 (red line in Figure 7), the value of x is 0.08 g CeO2/g MnOX, which converted to the mass fraction of Ce is 3.2%. The intersection is the demarcation of the two forms of Ce species on the surface of the MnOX carrier, and that is the monolayer dispersion threshold of the system [38]. The monolayer dispersion threshold (3.2%) is consistent with the turning points appeared in all the above characterization results. Catalysts with a monolayer-dispersed active component obviously show better activity. Since the Ce content is closest to the threshold, the fresh and reacted 3% CeO2-MnOX-300 were selected for XPS text to detect the element valence and content of the interfaces with monolayer-dispersed Ce. The results are showed in Figure 8 and Table 3. In the Mn 2p spectra, the peaks around 643 eV and 641 eV are assigned to Mn 4+ and Mn 3+ (or Mn 2+ ) species [42]. The ratio of Mn 4+ /(Mn 2+ + Mn 3+ ) decreases from 0.32 (fresh) to 0.22 (reacted), suggesting that the Mn ions tend to get electrons in the systems (the valence of partial Mn ions dropped from +4 to +2 and +3). In the Ce 3d spectra, the peaks of 3d3/2 and 3d5/2 spin-orbit component were marked as u and v, respectively. The peaks labeled as v, v2, v3, u, u2 and u3 belong to Ce 4+ , and the v1 and u1 belong to Ce 3+ [41,43]. The ratios of Ce 4+ /Ce 3+ decreased from 9.78 to 9.33 after the catalytic reaction, decreased slightly, indicating The monolayer dispersion threshold (3.2%) is consistent with the turning points appeared in all the above characterization results. Catalysts with a monolayer-dispersed active component obviously show better activity. Since the Ce content is closest to the threshold, the fresh and reacted 3% CeO 2 -MnO X -300 were selected for XPS text to detect the element valence and content of the interfaces with monolayer-dispersed Ce. The results are showed in Figure 8 and Table 3. In the Mn 2p spectra, the peaks around 643 eV and 641 eV are assigned to Mn 4+ and Mn 3+ (or Mn 2+ ) species [42]. The ratio of Mn 4+ /(Mn 2+ + Mn 3+ ) decreases from 0.32 (fresh) to 0.22 (reacted), suggesting that the Mn ions tend to get electrons in the systems (the valence of partial Mn ions dropped from +4 to +2 and +3). In the Ce 3d spectra, the peaks of 3d 3/2 and 3d 5/2 spin-orbit component were marked as u and v, respectively. The peaks labeled as v, v 2 , v 3 , u, u 2 and u 3 belong to Ce 4+ , and the v 1 and u 1 belong to Ce 3+ [41,43]. The ratios of Ce 4+ /Ce 3+ decreased from 9.78 to 9.33 after the catalytic reaction, decreased slightly, indicating that the part of Ce 3+ expended in reaction irreversibly. Obviously, Ce 3+ is helpful to the promotion of catalytic activity. The spectrum of O 1 s could be resolve into three characteristic peaks: surface oxygen (O sur ) at 530-532 eV, adsorbed oxygen (O ads ) at 533-534 eV and lattice oxygen (O latt ) at 529-530 eV [42,44]. The peak intensities of O latt , O ads and O sur are all detectable changed after reaction. Furthermore, the loop of oxygen can be inferred from the increase/decrease in oxygen species ratios. The reaction consumed O ads and O sur directly, herein the oxygen atoms in lattice overflow and replenish to the surface, while the O 2 in the gas phase is also adsorbed to the catalyst surface to supplement the surface and crystal phase oxygen. All the above XPS results reveal that Ce 4+ /Ce 3+ , Mn 4+ /(Mn 2+ +Mn 3+ ), O latt , O ads and O sur are all involved in toluene catalytic oxidation. The monolayer-dispersed state Ce makes the valence states of elements in the system more variable. Moreover, the abundant active site number and variety are the main reason for the high activity of the wCeO 2 -MnO X (w ≤ 3%).

H2-TPR Analysis
Temperature-programmed reduction (H2-TPR) was carried out over wCeO2-MnOX to investigate the effect of the impact of Ce-Mn interfaces with the Ce different states on the redox properties. Results are presented in Figure 9 and Table S2. The reduction of pure MnOX proceeds in two peaks at 334 °C and 472 °C, which are consistent with reduction steps: Mn2O3→Mn3O4→MnO [45], respectively. As compared with the pure MnOX, the wCeO2-MnOX-300 samples also exhibit two main H2 consumption peaks, while all peaks have shifted to a lower temperature at different extend. The position of higher temperature peaks (around 400 °C) decreases distinctly with the Ce content increase in the range of 1%-3%, while basically remains stable in the range of 3%-10%. The shift of the lower temperature peaks (around 285 °C) also shows the same behavior. Particularly, the samples with Ce content below or slightly above the threshold show peaks at around 210 °C, which are caused by MnO2→Mn2O3 [46]. It is well demonstrated that the monolayer-dispersed Ce induces the Mn at the interface to exhibit more abundant valence states and significantly enhances the redox activity of manganese, while the crystalline phase CeO2 does not. In summary, the monolayer-dispersed threshold plays a key role in reducibility and activity of catalysts.

H 2 -TPR Analysis
Temperature-programmed reduction (H 2 -TPR) was carried out over wCeO 2 -MnO X to investigate the effect of the impact of Ce-Mn interfaces with the Ce different states on the redox properties. Results are presented in Figure 9 and Table S2. The reduction of pure MnO X proceeds in two peaks at 334 • C and 472 • C, which are consistent with reduction steps: Mn 2 O 3 →Mn 3 O 4 →MnO [45], respectively. As compared with the pure MnO X , the wCeO 2 -MnO X -300 samples also exhibit two main H 2 consumption peaks, while all peaks have shifted to a lower temperature at different extend. The position of higher temperature peaks (around 400 • C) decreases distinctly with the Ce content increase in the range of 1-3%, while basically remains stable in the range of 3-10%. The shift of the lower temperature peaks (around 285 • C) also shows the same behavior. Particularly, the samples with Ce content below or slightly above the threshold show peaks at around 210 • C, which are caused by MnO 2 →Mn 2 O 3 [46]. It is well demonstrated that the monolayer-dispersed Ce induces the Mn at the interface to exhibit more abundant valence states and significantly enhances the redox activity of manganese, while the crystalline phase CeO 2 does not. In summary, the monolayer-dispersed threshold plays a key role in reducibility and activity of catalysts. Catalysts 2020, 10, x FOR PEER REVIEW 11 of 17 Figure 9. H2-TPR of wCeO2-MnOX loading.

UV-Vis DRS Analysis
To detect the surface coordination and different oxidation state of wCeO2-MnOX, the UV-Vis diffuse reflectance spectra were characterized and shown in Figure 10. As previously reported, crystalline Mn3O4 has a band gap of 2.175 eV and the corresponding absorption wavelength is 570 nm [47]. The spectrum of 1% CeO2-MnOX fits this well. All samples show feeble bands at 505-509 nm and 270 nm, which are assigned to the 6 A1 g→ 4 T2 g crystal field transitions of Mn 2+ and the charge transfer transition of O 2− →Mn 3+ under the circumstance of the MnOX [12,48]. In general, the UV-Vis spectra of pure CeO2 exhibits three-band centers at around 255, 285 and 340 nm. The latter two bands are caused by O 2− →Ce 4+ , whereas the vague former maxima correspond to O 2− →Ce 3+ transitions [49]. Only the bands corresponding to O 2− →Ce 3+ charge transfer transition appear at 238 nm in Figure 9. The absorption edge of the CeO2 interband transition is sensitive to crystal size [50]. Especially, when the size is <10 nm, the blue shift can be clearly observed in 8% and 10% CeO2-MnOX, whose diameters are 6.7 nm and 3.9 nm according to XRD. The f→d transitions of Ce 3+ species at 207 and 219 nm only occur in monolayer-dispersed (1%-3%) and low crystallinity (5%) samples. The above results indicate that the interaction between Mn and monolayer-dispersed Ce increases the species and quantity of metal ions at low valence states on the Ce-Mn interface. It was the Ce-Mn interface that significantly expanded the light absorption range of the integral wCeO2-MnOX-300, which have better electron transfer performance and catalytic activity than MnOX.

UV-Vis DRS Analysis
To detect the surface coordination and different oxidation state of wCeO 2 -MnO X , the UV-Vis diffuse reflectance spectra were characterized and shown in Figure 10. As previously reported, crystalline Mn 3 O 4 has a band gap of 2.175 eV and the corresponding absorption wavelength is 570 nm [47]. The spectrum of 1% CeO 2 -MnO X fits this well. All samples show feeble bands at 505-509 nm and 270 nm, which are assigned to the 6 A 1 g → 4 T 2 g crystal field transitions of Mn 2+ and the charge transfer transition of O 2− →Mn 3+ under the circumstance of the MnO X [12,48]. In general, the UV-Vis spectra of pure CeO 2 exhibits three-band centers at around 255, 285 and 340 nm. The latter two bands are caused by O 2− →Ce 4+ , whereas the vague former maxima correspond to O 2− →Ce 3+ transitions [49]. Only the bands corresponding to O 2− →Ce 3+ charge transfer transition appear at 238 nm in Figure 9. The absorption edge of the CeO 2 interband transition is sensitive to crystal size [50]. Especially, when the size is <10 nm, the blue shift can be clearly observed in 8% and 10% CeO 2 -MnO X , whose diameters are 6.7 nm and 3.9 nm according to XRD. The f→d transitions of Ce 3+ species at 207 and 219 nm only occur in monolayer-dispersed (1-3%) and low crystallinity (5%) samples. The above results indicate that the interaction between Mn and monolayer-dispersed Ce increases the species and quantity of metal ions at low valence states on the Ce-Mn interface. It was the Ce-Mn interface that significantly expanded the light absorption range of the integral wCeO 2 -MnO X -300, which have better electron transfer performance and catalytic activity than MnO X . The embedded model is a theory generally accepted by researchers in the field of catalysis [51]. The behaviors between CeO2 and MnOX compounds can also be explained by an embedded model, as shown in Figure S5. Under appropriate conditions, cations of CeO2 entered the lattice intervals and vacancies on the surface of Mn3O4, while the ortho O 2− capped the cationic sites to dispel the excess The embedded model is a theory generally accepted by researchers in the field of catalysis [51]. The behaviors between CeO 2 and MnO X compounds can also be explained by an embedded model, as shown in Figure S5. Under appropriate conditions, cations of CeO 2 entered the lattice intervals and vacancies on the surface of Mn 3 O 4 , while the ortho O 2− capped the cationic sites to dispel the excess positive charge. The lattice distortion of Mn 3 O 4 is caused by Ce entering the lattice intervals and vacancies, which leads to the increase of oxygen vacancy and surface oxygen activity. Therefore, the catalyst activity promotes correlatively with the amount of Ce. It is worth noting that the surface crystal is regular when the content of Ce on the surface reaches the monolayer dispersion threshold. There are no excess efficient sites on the MnO X surface to accommodate Ce ions. Then the Ce ions begin to accumulate in the upper layer, and form CeO 2 crystals. Hence, the properties at the interface of the CeO 2 -MnO X do not further change with the increase of the Ce content.

Synthesis of Mn-MOF
In a typical procedure [52], MnCl 2 (15 mmol) and H 3 BTC (10 mmol) were dissolved in ethanol solution (50 mL) under vigorous agitation at room temperature. After MnCl 2 is completely dissolved, 2 mL triethylamine was added into the above solution dropwise and kept stirring at medium speed. After reaction for 6 h, the white precipitate in the solution was separated using vacuum suction filtration. The white precipitate was washed with ethanol for 3 times and dried at 60 • C under vacuum for 24 h. Then the precipitate was grinded, and the resulting white powder is the sacrificial template.

Synthesis of CeO 2 -MnO X
Synthesis of CeO 2 -MnO X was based on the following procedure: First, Mn-MOF (2.0 g) and Ce(NO 3 ) 3 •6H 2 O (0.062 g) were dissolved in ethanol solution (30 mL) under stirring at room temperature. Then let the mixture stand still for 24 h. Finally, the as-synthesized product was completely dried at 120 • C (the heating rate is 2 • C min −1 ) and calcinated in the air at a particular temperature for 12 h to synthesize the 1%-CeO 2 -MnO X nanoparticles. In addition, 3% CeO 2 -MnO X , 5% CeO 2 -MnO X , 8% CeO 2 -MnO X , 10% CeO 2 -MnO X were prepared in the same procedure. Catalysts were coded as wCeO 2 -MnO X (w referred to the mass fraction of Ce).

Material Characterization
The crystallinity of the catalysts was studied by powder X-ray diffraction (XRD) on a D8 ADVANCE diffractometer (Bruker, Germany) with Cu-Kα radiation (40 kV, 40 mA). The patterns were obtained between 2θ = 10-90 • with a step size of 0.02 • . Nitrogen adsorption/desorption isotherms were performed on an ASAP2020 M analyzer (Micromeritics, Norcross, GA, USA). All samples were outgassed at 150 • C in vacuum for 8 h before measurement. The thermal stability of samples was characterized by thermogravimetric analysis (TGA) on a STA449C apparatus (NETZSCH, Selb, Germany) at a heating rate of 10 • C min −1 . Elemental analysis (EA) was conducted on FLASH 2000 (Thermo Scientific, Waltham, MA, USA). The Ce contents in CeO 2 -MnO X samples were investigated by inductively coupled plasma optical emission spectrometry (ICP-OES) on Varian 720 (USA). The morphology and structure of samples were obtained by transmission electron microscopy (TEM) (FEI f20, Hillsboro, OR, USA) and scanning electron microscopy (SEM) (Hitachi S4800/8010, Tokyo, Japan). The elemental distribution over the selected region was acquired on an energy-dispersive X-ray spectrometer (EDS) attached to the SEM instrument. Temperature-programmed reduction (H 2 -TPR) was performed on AutoChem (Micromeritics, Norcross, GA, USA) under 10% H 2 /Ar mixture gas at a rate of 10 • C min −1 up to 900 • C. Moreover, the outlet exhaust was detected by TCD. The valence states of Mn, Ce and O were studied by EscaLab 250Xi X-ray photoelectron spectrometry (XPS) (Thermo Scientific, Waltham, MA, USA). The Raman spectra of the catalysts were recorded in a LabRAM HR Evolution Laser Raman Spectrometer (HYJ, Arras, France) with a He-Ne laser and a CDD detector. Visible Raman spectra were collected using the exciting line at 532 cm −1 from 300-800 cm −1 . UV-Vis diffuse reflectance spectra (DRS) measurements were taken in the range of 200-800 nm using a UV-2700 spectrophotometer (Shimadzu, Kyoto, Japan).

Catalytic Activity Evaluation
An evaluation of catalytic activities was performed on a toluene temperature-programmed oxidation (TPO) apparatus with a continuous flow microreactor made quartz (8 mm i.d., 500 mm length). Per 200 mg sample mixed into 800 mg of silica to avoid reaction runaway. All the particles were packed at the bed of the reactor. The reactant mixture gas (1000 ppm Toluene, 20% O 2 /N 2 ) flowed through the reactor at a rate of 160 mL min −1 , corresponding to the weight hourly space velocity (WHSV) at 48,000 mL g −1 h −1 . The effluent gases were monitored online by gas chromatography (GC-2014C, Shimadzu, Japan) equipped with FID. The toluene conversion (Xtoluene) was analyzed by the inlet and outlet concentration, which was calculated based on the following equation: where X toluene denotes the toluene conversion at a certain temperature; C in (ppm) and C out (ppm) denotes the concentrations of toluene in the inlet and outlet gas, respectively.

Conclusions
In summary, a series of porous composite oxides (wCeO 2 -MnO X ) with high dispersity and activity were successfully prepared via a simple Mn-MOFs templated pyrolytic transformation at 300 • C. The MOF sacrificial template with immersion treatment helps to synthesize the composite oxide with high dispersion and controllable interface. These as-prepared wCeO 2 -MnO X catalysts exhibited novel morphologies and two-stage performance improvement in toluene oxidation. This was mainly because the Ce had two-dispersed states on the MnO X interface. The monolayer dispersion threshold (3.2% wt.) was the sign of the monolayer dispersion state turning to crystalline and the key indicator of system activity. The Ce-Mn interfaces with monolayer dispersion feature were crucial for efficient catalytic activity. The monolayer dispersion state Ce changed the chemical property of pure Mn 3 O 4 surface, which significantly improved the reducibility, oxygen mobility, metal ion valence state abundance and electron transfer ability of catalysts. And the crystal Ce was much more like a fence, separating the particles and only enhanced the activity by changing physical structure parameters, such as particle size and specific surface area. Obviously, the monolayer-dispersed Ce was more efficient in improving the catalytic activity.