Highly Active and Sulfur‐Resistant Fe–N<sub>4</sub> Sites in Porous Carbon Nitride for the Oxidation of H<sub>2</sub>S into Elemental Sulfur

Lei, Ganchang; Tong, Yawen; Liu, Fujian; Xiao, Yihong; Lin, Wei; Zhang, Yongfan; Au, Chak Tong; Jiang, Lilong

doi:10.1002/smll.202003904

Cited by 42 publications

(26 citation statements)

References 69 publications

(77 reference statements)

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“…The same results are displayed in the Fe 2p XPS spectrum (Figure S7, Supporting Information). [49][50][51] The N 1s XPS spectrum of SA-Fe-TCN features three peaks at 395.1, 396.4, and 397.8 eV (Figure 3b). The first two peaks are typically found in CN and can be assigned to pyrrolic and pyridinic N, respectively.…”

Section: Resultsmentioning

confidence: 99%

A Unique Fe–N₄ Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic CH Activation with High Efficiency and Selectivity

Xiao

Ruan

et al. 2022

Advanced Materials

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examples is the oxidation of ethylbenzene, yielding acetophenone that is an important raw material for producing medicines, fragrances, cellulose ethers, resins, flavoring agents, and many others. [6][7][8][9] However, the CH bond of ethylbenzene is so strong that its activation and cleavage usually require harsh conditions such as high temperatures. [10][11][12][13][14][15] In general, tert-butyl hydroperoxide or hydrogen peroxide is utilized to create hydroxyl radicals (•OH) with the help of a catalyst. •OH is highly reactive and can easily oxidize ethylbenzene. Nonetheless, the reaction also creates phenethyl alcohol and other byproducts, resulting in reduced selectivity with respect to acetophenone. [16][17][18][19] Given the great utility of this organic compound, it is necessary to develop strategies for improving the reaction selectivity under mild conditions. As a type of sustainable technology, photocatalysis that is able to use solar energy to generate reactive species has already shown tremendous potentials in organic synthesis.Polymeric carbon nitride (CN) as a metal-free photocatalyst has captured widespread attention. [20][21][22][23][24] Under light illumination, free electrons [25][26][27][28] and holes [29][30][31][32] are generated in CN, Selective oxidation of CH bonds is one of the most important reactions in organic synthesis. However, activation of the α-CH bond of ethylbenzene by use of photocatalysis-generated superoxide anions (O 2 •− ) remains a challenge. Herein, the formation of individual Fe atoms on polymeric carbon nitride (CN), that activates O 2 to create O 2 •− for facilitating the reaction of ethylbenzene to form acetophenone, is demonstrated. By utilizing density functional theory and materials characterization techniques, it is shown that individual Fe atoms are coordinated to four N atoms of CN and the resultant low-spin Fe-N 4 system (t 2g 6 e g 0 ) is not only a great adsorption site for oxygen molecules, but also allows for fast transfer of electrons generated in the CN framework to adsorbed O 2 , producing O 2 •− . The oxidation reaction of ethylbenzene triggered by O 2•− ions turns out to have a high conversion rate of 99% as well as an acetophenone selectivity of 99%, which can be ascribed to a novel reaction pathway that is different from the conventional route involving hydroxyl radicals and the production of phenethyl alcohol. Furthermore, it possesses great potential for other CH activation reactions besides ethylbenzene oxidation.

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Section: Resultsmentioning

confidence: 99%

A Unique Fe–N₄ Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic CH Activation with High Efficiency and Selectivity

Xiao

Ruan

et al. 2022

Advanced Materials

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“…The excellent activity as well as steam and sulfur-resistance of the emblematic Fe-N-C system -consisting here of Fe-N4 centers confined in polymeric carbon nitride through a copolymerization approach -for gas-phase H2S oxidation into elemental sulfur was recently reported by Lei et al [263]. Based on DFT calculations, the authors propose H2S and O2 dissociative adsorptions at (probably separate) Fe-N4 centers, leading to HS-Fe-N4 and O* radical species, which in turn exothermally generate S and H2O (Figure 8a).…”

Section: Other Reactionsmentioning

confidence: 74%

Supported Metal Single‐Atom Thermocatalysts for Oxidation Reactions

Piccolo

Loridant

Christopher

2022

Supported Metal Single Atom Catalysis

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The interest in single-metal-atom dispersion in heterogeneous catalysis has existed since the 1950s with spectroscopic investigations of rhodium "single-site" catalysts supported on alumina, and more recently with oxometallate monomers for selective oxidation reactions. A decade ago, advances in electron microscopy intensified the interest of the catalysis community in controlling the dispersion of supported metals down to the single-atom active site level and revealing their intrinsic catalytic properties. Pioneering works in the ever-growing field of single-atom catalysis investigated late transition metals (group 8 to 11) supported on transition metal oxides for the CO oxidation and water-gas shift reactions. Since then, various single-atom catalysts, most often supported on oxides, have been evaluated in a broad panel of thermal oxidation reactions, and have often shown remarkable performances. Besides CO oxidation over oxidesupported noble metals, which represents the major part of the literature, this chapter reviews the main classes of oxidation reactions, including total and selective oxidations of hydrocarbons and oxygenates, on 2 oxide-or carbon-supported catalysts. Throughout the chapter, we emphasize several aspects that we consider important, such as the coordination environment and stability of single metal atoms, as well as their compared performance with supported nanoparticles. Figure 3. a) Aberration-corrected STEM image of Pt atoms (identified by yellow circles) on ca. 5 nm diameter anatase TiO2 particles. Adapted with permission from [72], Copyright 2017 ACS. b) CO probemolecule FTIR spectra of a Pt/TiO2 SAC as a function of temperature during a TPD measurement. c) DFT-calculated structure of CO bound to PtO2 adsorbed at a TiO2(145) step edge. b and c adapted with permission from [73], Copyright 2018 Elsevier. d) Schematic showing the structural transformation of isolated Pt species as a function of environmental conditions. Adapted with permission from [74],Copyright 2019 Springer Nature. e) DFT-calculated reaction pathway for CO oxidation on a Pd/TiO2 SAC that was supported by spectroscopic and kinetic analyses. Adapted with permission from [75],

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“…It is noted that the released CN X and CH X fragments act as a soft template for pore formation during the pyrolysis, thus, expanding the BET surface area of xCo-N/NC. [43] For comparison purposes, sample of Co nanoparticles (Co loading of 5.2 wt%) dispersed on NC surface (Co-NPs/NC) was prepared. The TEM images in Figure S5a-c (Supporting Information) reveal that the Co nanoparticles are dispersed on the nitrogen-doped carbon, indicating the aggregation of Co atoms.…”

Section: Resultsmentioning

confidence: 99%

Highly Poison‐Resistant Single‐Atom Co–N₄ Active Sites with Superior Operational Stability over 460 h for H₂S Catalytic Oxidation

Lei

Tong

Zheng

et al. 2021

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Efficient catalytic elimination of hydrogen sulfide (H2S) with high activity and durability in nature gas and blast‐furnace gas is very critical for both fundamental catalytic research and applied environmental chemistry. Herein, atomically dispersed Co atom catalysts with Co–N4 sites that can transform H2S into S with conversion rate of ≈100% are designed and prepared. The representative 4Co‐N/NC achieves a sulfur yield of nearly 100% and TOF(Co) of 869 h–1 at 180 °C. Importantly, remarkable long‐term durability is achieved as well, with no obvious loss of catalytic activity in the run of 460 h, outperforming most of the reported catalysts. The short bond length and strong cooperation of Co–N are beneficial to improve the structural stability of the Co–N4 centers, and significantly enhanced resistance of water and sulfation over single‐atom Co‐catalyst. The present mechanism involves the stepwise hydrogen transfer process via the adsorbed *HOO and *HS intermediates.

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Highly Active and Sulfur‐Resistant Fe–N₄ Sites in Porous Carbon Nitride for the Oxidation of H₂S into Elemental Sulfur

Cited by 42 publications

References 69 publications

A Unique Fe–N₄ Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic CH Activation with High Efficiency and Selectivity

A Unique Fe–N₄ Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic CH Activation with High Efficiency and Selectivity

Supported Metal Single‐Atom Thermocatalysts for Oxidation Reactions

Highly Poison‐Resistant Single‐Atom Co–N₄ Active Sites with Superior Operational Stability over 460 h for H₂S Catalytic Oxidation

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Highly Active and Sulfur‐Resistant Fe–N4 Sites in Porous Carbon Nitride for the Oxidation of H2S into Elemental Sulfur

Cited by 42 publications

References 69 publications

A Unique Fe–N4 Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic CH Activation with High Efficiency and Selectivity

A Unique Fe–N4 Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic CH Activation with High Efficiency and Selectivity

Supported Metal Single‐Atom Thermocatalysts for Oxidation Reactions

Highly Poison‐Resistant Single‐Atom Co–N4 Active Sites with Superior Operational Stability over 460 h for H2S Catalytic Oxidation

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Product

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Highly Active and Sulfur‐Resistant Fe–N₄ Sites in Porous Carbon Nitride for the Oxidation of H₂S into Elemental Sulfur

A Unique Fe–N₄ Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic CH Activation with High Efficiency and Selectivity

A Unique Fe–N₄ Coordination System Enabling Transformation of Oxygen into Superoxide for Photocatalytic CH Activation with High Efficiency and Selectivity

Highly Poison‐Resistant Single‐Atom Co–N₄ Active Sites with Superior Operational Stability over 460 h for H₂S Catalytic Oxidation