Polymeric carbon nitride nanomesh as an efficient and durable metal-free catalyst for oxidative desulfurization

Shen, Lijuan; Lei, Ganchang; Fang, Yuanxing; Cao, Yanning; Wang, Xinchen; Jiang, Lilong

doi:10.1039/c7cc09211c

Cited by 108 publications

(65 citation statements)

References 40 publications

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“…Further increase of temperature leads to gradually decrease of sulfur selectivity. It is because side reactions are promoted at high temperatures, leading to deep oxidation of H2S (H2S + 3/2O2 → SO2 + H2O) or oxidation of the produced sulfur (S + O2 → SO2) [49]. Nevertheless, the sulfur selectivity is still higher than 89% for MIL-53(Fe) and MIL-53(Fe)-xH catalysts at 190 °C.…”

Section: Catalytic Activitymentioning

confidence: 99%

Morphology evolution of acetic acid-modulated MIL-53(Fe) for efficient selective oxidation of H2S

Zheng

Cao

et al. 2021

Chinese Journal of Catalysis

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Section: Catalytic Activitymentioning

confidence: 99%

Morphology evolution of acetic acid-modulated MIL-53(Fe) for efficient selective oxidation of H2S

Zheng

Cao

et al. 2021

Chinese Journal of Catalysis

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“…Polymeric carbon nitride (CN) was considered promising for the oxidative desulfurization in previous studies. [25][26][27][28][29] The CN is composed of infinite 2D layers of repeating tri-s-triazinebased "melon" rings. [30][31][32] Incomplete polymerization of CN would result in edges and/or defects sites, which are capable of anchoring metal atoms.…”

Section: Iron-based Catalysts Have Been Widely Studied For the Oxidatmentioning

confidence: 99%

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

Lei

Tong

Liu

et al. 2020

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Iron‐based catalysts have been widely studied for the oxidation of H2S into elemental S. However, the prevention of iron sites from deactivation remains a big challenge. Herein, a facile copolymerization strategy is proposed for the construction of isolated Fe sites confined in polymeric carbon nitride (CN) (Fe‐CNNχ). The as‐prepared Fe‐CNNχ catalysts possess unique 2D structure as well as electronic property, resulting in enlarged exposure of active sites and enhancement of redox performance. Combining systematic characterizations with density functional theory calculation, it is disclosed that the isolated Fe atoms prefer to occupy four‐coordinate doping configurations (Fe–N4). Such Fe–N4 centers favor the adsorption and activation of O2 and H2S. As a consequence, Fe‐CNNχ exhibit excellent catalytic activity for the catalytic oxidation of H2S to S. More importantly, the Fe‐CNNχ catalysts are resistant to water and sulfur poisoning, exhibiting outstanding catalytic stability (over 270 h of continuous operation), better than most of the reported catalysts.

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“…Metal-free systems of this type have successfully been scrutinized as selective and efficient catalytic materials for a number of industrially relevant oxidation [13][14][15][16][17][18] and reduction [19][20][21][22] processes or as valuable promoters of other challenging catalytic transformations [23,24]. Nanocarbonbased materials, particularly in the form of N-doped networks, have already been exploited as effective metal-free systems for the selective hydrogen sulfide oxidation to elemental sulfur from natural gas tails [16,[25][26][27][28][29][30][31][32][33]. The unique features of these single-phase systems (e.g., the absence of a metal active-phase, the prevalent basic surface character of the N-doped samples together with reduced production cost and environmental impact) have largely contributed to overcome the drawbacks classically encountered with metal nanoparticles-based catalysts.…”

Section: Introductionmentioning

confidence: 99%

Tailoring Properties of Metal-Free Catalysts for the Highly Efficient Desulfurization of Sour Gases under Harsh Conditions

et al. 2021

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Carbon-based nanomaterials, particularly in the form of N-doped networks, are receiving the attention of the catalysis community as effective metal-free systems for a relatively wide range of industrially relevant transformations. Among them, they have drawn attention as highly valuable and durable catalysts for the selective hydrogen sulfide oxidation to elemental sulfur in the treatment of natural gas. In this contribution, we report the outstanding performance of N-C/SiC based composites obtained by the surface coating of a non-oxide ceramic with a mesoporous N-doped carbon phase, starting from commercially available and cheap food-grade components. Our study points out on the importance of controlling the chemical and morphological properties of the N-C phase to get more effective and robust catalysts suitable to operate H2S removal from sour (acid) gases under severe desulfurization conditions (high GHSVs and concentrations of aromatics as sour gas stream contaminants). We firstly discuss the optimization of the SiC impregnation/thermal treatment sequences for the N-C phase growth as well as on the role of aromatic contaminants in concentrations as high as 4 vol.% on the catalyst performance and its stability on run. A long-term desulfurization process (up to 720 h), in the presence of intermittent toluene rates (as aromatic contaminant) and variable operative temperatures, has been used to validate the excellent performance of our optimized N-C2/SiC catalyst as well as to rationalize its unique stability and coke-resistance on run.

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Polymeric carbon nitride nanomesh as an efficient and durable metal-free catalyst for oxidative desulfurization

Cited by 108 publications

References 40 publications

Morphology evolution of acetic acid-modulated MIL-53(Fe) for efficient selective oxidation of H2S

Morphology evolution of acetic acid-modulated MIL-53(Fe) for efficient selective oxidation of H2S

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

Tailoring Properties of Metal-Free Catalysts for the Highly Efficient Desulfurization of Sour Gases under Harsh Conditions

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Polymeric carbon nitride nanomesh as an efficient and durable metal-free catalyst for oxidative desulfurization

Cited by 108 publications

References 40 publications

Morphology evolution of acetic acid-modulated MIL-53(Fe) for efficient selective oxidation of H2S

Morphology evolution of acetic acid-modulated MIL-53(Fe) for efficient selective oxidation of H2S

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

Tailoring Properties of Metal-Free Catalysts for the Highly Efficient Desulfurization of Sour Gases under Harsh Conditions

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