Evolution of oxygen vacancies in MnOx-CeO2 mixed oxides for soot oxidation

“…Table 2 Figure 4 shows the N 2 adsorption-desorption isotherms. All samples have typical type IV isotherm showing a hysteresis loop at high relative pressures, which is associated with capillary condensation representative of mesoporous materials [24][25][26][27][28]. This is confirmed by the mean pore size shown in Table 2, where all samples have a pore size in the range of mesopores (2-50 nm).…”

“…The adsorbed oxygen starts to reacts with soot at temperatures below 500 • C, and an increment in the mass loss, attributed to the soot combustion, is clearly detected. In contrast, the preservation of the perovskite structure with high Mn 3+ content in Mn1 and Mn4, which correlates with the formation of surface oxygen vacancies, can produce a competing oxidation reaction between soot combustion and the oxidation of Mn 3+ to Mn 4+ , resulting in rapidly filled surface oxygen vacancies and low mass loss (see Figure 5c), as described by Xueting et al [27]. However, at temperatures higher than 500 • C, oxygen migrates from the bulk to the catalyst surface.…”

“…By increasing the temperature, oxygen migrates from the bulk to the surface, enhanced by the redox pair Mn 3+ /Mn 4+ and the existence of Ti 3+ /Ti 4+ species (Red arrow in Figure 6). Mn1, with high Mn 3+ content and oxygen vacancies, can transport oxygen from the bulk to the surface and enhance the soot oxidation rate (Green arrow in Figure 6) [13,27]. Another possibility causing the behavior observed in Figure 5c is the better dispersion of Mn species on the surface of Mn1 and Mn4 catalysts against Mn8.…”

“…The deconvolution analysis shows two well defined peaks in all samples located at 528.8 and 530.6 eV, which are respectively attributed to lattice oxygen (Olat) from the perovskite structure or surface segregated oxides and surface adsorbed oxygen (Oads), associated with defect oxides [27], carbonates or hydroxyl species, as well as weakly bonded oxygen adsorbed on the surface [13,26]. The Oads/Olat ratio shown in Table 2 demonstrates high Oads in the Mn1 sample, which can be attributed to the structural defects produced by the Mn 3+ /Mn 4+ ratio shown in Table 2 [1].…”

“…However, at temperatures higher than 500 • C, oxygen migrates from the bulk to the catalyst surface. The Mn1 sample, rich in structural defects (as shown in Figure 3b), is the best catalyst for oxygen transportation via the ion-mobility mechanism [13,27], which promotes the combustion of soot. Mass loss increases dramatically as a consequence.…”

Effect of Dopant Loading on the Structural and Catalytic Properties of Mn-Doped SrTiO3 Catalysts for Catalytic Soot Combustion

“…Table 2 Figure 4 shows the N 2 adsorption-desorption isotherms. All samples have typical type IV isotherm showing a hysteresis loop at high relative pressures, which is associated with capillary condensation representative of mesoporous materials [24][25][26][27][28]. This is confirmed by the mean pore size shown in Table 2, where all samples have a pore size in the range of mesopores (2-50 nm).…”

“…The adsorbed oxygen starts to reacts with soot at temperatures below 500 • C, and an increment in the mass loss, attributed to the soot combustion, is clearly detected. In contrast, the preservation of the perovskite structure with high Mn 3+ content in Mn1 and Mn4, which correlates with the formation of surface oxygen vacancies, can produce a competing oxidation reaction between soot combustion and the oxidation of Mn 3+ to Mn 4+ , resulting in rapidly filled surface oxygen vacancies and low mass loss (see Figure 5c), as described by Xueting et al [27]. However, at temperatures higher than 500 • C, oxygen migrates from the bulk to the catalyst surface.…”

“…By increasing the temperature, oxygen migrates from the bulk to the surface, enhanced by the redox pair Mn 3+ /Mn 4+ and the existence of Ti 3+ /Ti 4+ species (Red arrow in Figure 6). Mn1, with high Mn 3+ content and oxygen vacancies, can transport oxygen from the bulk to the surface and enhance the soot oxidation rate (Green arrow in Figure 6) [13,27]. Another possibility causing the behavior observed in Figure 5c is the better dispersion of Mn species on the surface of Mn1 and Mn4 catalysts against Mn8.…”

“…The deconvolution analysis shows two well defined peaks in all samples located at 528.8 and 530.6 eV, which are respectively attributed to lattice oxygen (Olat) from the perovskite structure or surface segregated oxides and surface adsorbed oxygen (Oads), associated with defect oxides [27], carbonates or hydroxyl species, as well as weakly bonded oxygen adsorbed on the surface [13,26]. The Oads/Olat ratio shown in Table 2 demonstrates high Oads in the Mn1 sample, which can be attributed to the structural defects produced by the Mn 3+ /Mn 4+ ratio shown in Table 2 [1].…”

“…However, at temperatures higher than 500 • C, oxygen migrates from the bulk to the catalyst surface. The Mn1 sample, rich in structural defects (as shown in Figure 3b), is the best catalyst for oxygen transportation via the ion-mobility mechanism [13,27], which promotes the combustion of soot. Mass loss increases dramatically as a consequence.…”

Effect of Dopant Loading on the Structural and Catalytic Properties of Mn-Doped SrTiO3 Catalysts for Catalytic Soot Combustion

Oxygen Vacancies‐Rich Metal Oxide for Electrocatalytic Nitrogen Cycle

Carbon Dots in a Matrix: Energy‐Transfer‐Enhanced Room‐Temperature Red Phosphorescence