Progress of Catalytic Oxidation of Formaldehyde over Manganese Oxides

Zhu, Silong; Wang, Jie; Nie, Li

doi:10.1002/slct.201902701

Cited by 24 publications

(25 citation statements)

References 109 publications

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“…Interestingly, the compiled T 100 (the temperature for achieving total conversion) values did not surpass 200 • C, which is a very useful feature for low power consumption sensors. Similar observations can be drawn from a more recent review [40]. β-MnO 2 was found by Li et al [41] as the most active phase toward CO oxidation with a T 90 of 109 • C. In the case of Mn oxides, the relationship with sensing applications is not very well defined, very few sensing papers having been published.…”

Section: Manganese Oxidessupporting

confidence: 76%

How Chemoresistive Sensors Can Learn from Heterogeneous Catalysis. Hints, Issues, and Perspectives

et al. 2021

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The connection between heterogeneous catalysis and chemoresistive sensors is emerging more and more clearly, as concerns the well-known case of supported noble metals nanoparticles. On the other hand, it appears that a clear connection has not been set up yet for metal oxide catalysts. In particular, the catalytic properties of several different oxides hold the promise for specifically designed gas sensors in terms of selectivity towards given classes of analytes. In this review, several well-known metal oxide catalysts will be considered by first exposing solidly established catalytic properties that emerge from related literature perusal. On this basis, existing gas-sensing applications will be discussed and related, when possible, with the obtained catalysis results. Then, further potential sensing applications will be proposed based on the affinity of the catalytic pathways and possible sensing pathways. It will appear that dialogue with heterogeneous catalysis may help workers in chemoresistive sensors to design new systems and to gain remarkable insight into the existing sensing properties, in particular by applying the approaches and techniques typical of catalysis. However, several divergence points will appear between metal oxide catalysis and gas-sensing. Nevertheless, it will be pointed out how such divergences just push to a closer exchange between the two fields by using the catalysis knowledge as a toolbox for investigating the sensing mechanisms.

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Section: Manganese Oxidessupporting

confidence: 76%

How Chemoresistive Sensors Can Learn from Heterogeneous Catalysis. Hints, Issues, and Perspectives

et al. 2021

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“…1−3 From a chemical point of view, MnO x has been widely applied in environmental waste treatment, 1,4−8 water oxidation in artificial photosynthesis, 9−12 batteries, 13,14 and supercapacitors, 15−17 to just name a few. As a catalyst, the catalytic performance and reaction mechanism of the MnO x material vary with its valence state 1,4 and Mn−O bond strength. 1,3 Furthermore, different surface facets and morphologies of MnO x nanostructures often lead to diverse catalytic performance.…”

Section: Introductionmentioning

confidence: 99%

“…As a catalyst, the catalytic performance and reaction mechanism of the MnO x material vary with its valence state 1,4 and Mn−O bond strength. 1,3 Furthermore, different surface facets and morphologies of MnO x nanostructures often lead to diverse catalytic performance. [1][2][3]18 Consequently, the controllable preparation of MnO x material is of great importance for improving their catalytic performance.…”

Section: Introductionmentioning

confidence: 99%

“…1,3 Furthermore, different surface facets and morphologies of MnO x nanostructures often lead to diverse catalytic performance. [1][2][3]18 Consequently, the controllable preparation of MnO x material is of great importance for improving their catalytic performance.…”

Section: Introductionmentioning

confidence: 99%

“…Manganese oxide (MnO x ) crystallizes naturally as minerals in more than 30 different structures, such as MnO, Mn 3 O 4 , Mn 2 O 3 , and MnO 2 . These manganese oxides present a number of excellent physical and chemical properties, such as facile oxygen mobility, enhanced oxygen storage capacitance, fast cation diffusion with high charge–discharge rates, environmental friendliness, and low cost. − From a chemical point of view, MnO x has been widely applied in environmental waste treatment, ,− water oxidation in artificial photosynthesis, − batteries, , and supercapacitors, − to just name a few. As a catalyst, the catalytic performance and reaction mechanism of the MnO x material vary with its valence state , and Mn–O bond strength. , Furthermore, different surface facets and morphologies of MnO x nanostructures often lead to diverse catalytic performance. − , Consequently, the controllable preparation of MnO x material is of great importance for improving their catalytic performance.…”

Section: Introductionmentioning

confidence: 99%

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Dynamic Structural Evolution of Mn–Au Alloy and MnO_x Nanostructures on Au(111) under Different Atmospheres

et al. 2021

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Construction of inverse oxide/metal model catalyst with specific chemical composition and interfacial structure is essential for clarifying their structure−performance relationship. This work describes the structural evolution of Mn−Au surface alloy and two-dimensional manganese oxide (MnO x ) islands on Au(111) surface under different treatment conditions. By employing near-ambient pressure scanning tunneling microscopy and Xray photoelectron spectroscopy, we can obtain four different MnO x structures. Among them, double-layer square lattice Mn 3 O 4 (001) and monolayer parallelogram-shaped Mn 3 O 4 are prepared by postannealing Mn−Au surface alloy in "oxygen-poor" and "oxygenrich" regimes, respectively. Annealing the monolayer parallelogram-shaped Mn 3 O 4 in vacuum to 700 K produces a double-layer structure consisting of Mn 3 O 4 top layer and MnO(111) bottom layer, while double-layer MnO(111) is formed after annealing in vacuum to 800 K. Our study lays the foundation for exploring the catalytic properties of inverse manganese oxide/metal model catalysts.

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Thermocatalytic Degradation of Gaseous Formaldehyde Using Transition Metal‐Based Catalysts

2023

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Formaldehyde (HCHO: FA) is one of the most abundant but hazardous gaseous pollutants. Transition metal oxide (TMO)-based thermocatalysts have gained much attention in its removal due to their excellent thermal stability and cost-effectiveness. Herein, a comprehensive review is offered to highlight the current progress in TMO-based thermocatalysts (e.g., manganese, cerium, cobalt, and their composites) in association with the strategies established for catalytic removal of FA. Efforts are hence made to describe the interactive role of key factors (e.g., exposed crystal facets, alkali metal/nitrogen modification, type of precursors, and alkali/acid treatment) governing the catalytic activity of TMO-based thermocatalysts against FA. Their performance has been evaluated further between two distinctive operation conditions (i.e., low versus high temperature) based on computational metrics such as reaction rate. Accordingly, the superiority of TMO-based composite catalysts over mono-and bi-metallic TMO catalysts is evident to reflect the abundant surface oxygen vacancies and enhanced FA adsorptivity of the former group. Finally, the present challenges and future prospects for TMO-based catalysts are discussed with respect to the catalytic oxidation of FA. This review is expected to offer valuable information to design and build high performance catalysts for the efficient degradation of volatile organic compounds.

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Progress of Catalytic Oxidation of Formaldehyde over Manganese Oxides

Cited by 24 publications

References 109 publications

How Chemoresistive Sensors Can Learn from Heterogeneous Catalysis. Hints, Issues, and Perspectives

How Chemoresistive Sensors Can Learn from Heterogeneous Catalysis. Hints, Issues, and Perspectives

Dynamic Structural Evolution of Mn–Au Alloy and MnO_x Nanostructures on Au(111) under Different Atmospheres

Thermocatalytic Degradation of Gaseous Formaldehyde Using Transition Metal‐Based Catalysts

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Progress of Catalytic Oxidation of Formaldehyde over Manganese Oxides

Cited by 24 publications

References 109 publications

How Chemoresistive Sensors Can Learn from Heterogeneous Catalysis. Hints, Issues, and Perspectives

How Chemoresistive Sensors Can Learn from Heterogeneous Catalysis. Hints, Issues, and Perspectives

Dynamic Structural Evolution of Mn–Au Alloy and MnOx Nanostructures on Au(111) under Different Atmospheres

Thermocatalytic Degradation of Gaseous Formaldehyde Using Transition Metal‐Based Catalysts

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Dynamic Structural Evolution of Mn–Au Alloy and MnO_x Nanostructures on Au(111) under Different Atmospheres