Harnessing the Synergistic Interplay of Fischer‐Tropsch Synthesis (Fe‐Co) Bimetallic Oxides in Na‐FeMnCo/HZSM‐5 Composite Catalyst for Syngas Conversion to Aromatic Hydrocarbons

Nawaz, Muhammad; Li, Minzhe; Saif, Maria; Song, Guiyao; Wang, Zi-Hao; Liu, Dianhua

doi:10.1002/cctc.202100024

Cited by 21 publications

(23 citation statements)

References 58 publications

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“…Theoretically, aromatics can be produced after coupling FTO catalysts and H-ZSM-5 using various catalyst integrated configurations including the dual-bed model, physical mixture model, and core–shell structure or zeolite supported model. , Moreover, the light aromatics components could be effectively tuned by neutralizing and/or sealing the exposed external acidic sites of HZSM-5 through silica deposition or impregnation of oxides of some metals. , Another effective approach is to tune the size of H-ZSM-5 crystallites Table S2 summarizes the typical catalysts for direct syngas conversion to aromatics, which are mainly obtained through a physical mixture or core–shell-structured model. − …”

Section: Aromatic Production Based On the Fts Routementioning

confidence: 99%

“…Many studies select Fe-based catalysts for the FTO reaction due to their broad operation temperature (200–400 °C), which will match the working temperature of the olefins to aromatics reaction over zeolite (300–400 °C). ,,, A reaction rate match between each step is required for the tandem reaction. Therefore, the fine design of highly efficient FTO catalyst and HZSM-5 zeolites with a suitable pore structure (i.e., hierarchical- or hollow-structured) and moderate acidity as well as their synergism play a crucial role for direct syngas conversion to aromatics.…”

Section: Aromatic Production Based On the Fts Routementioning

confidence: 99%

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Advances in Selectivity Control for Fischer–Tropsch Synthesis to Fuels and Chemicals with High Carbon Efficiency

Lin

et al. 2022

ACS Catal.

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Fischer–Tropsch synthesis (FTS) is a versatile technology to produce high-quality fuels and key building-block chemicals from syngas derived from nonpetroleum carbon resources such as coal, natural gas, shale gas, biomass, solid waste, and even CO2. However, the product selectivity of FTS is always limited by the Anderson–Schulz–Flory (ASF) distribution, and the key scientific problems including selectivity control, energy saving, and CO2 emission reduction still challenge the current FTS technology. Herein, we review recent significant progress in the field of FTS to obtain specific target products including fuels, olefins, aromatics, and higher alcohols with high selectivity. These achievements are enabled by developing highly efficient catalysts and a controlled reaction pathway based on an integrated process. The structural nature of catalytic active sites and established structure–performance relationships are clarified. Moreover, we specially focus on the carbon utilization efficiency, and the efforts to tune the preferential formation of value-added chemicals and strategies to reduce CO2 selectivity are summarized. The challenges and the perspectives for future FTS technology development with high carbon efficiency are also discussed.

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Section: Aromatic Production Based On the Fts Routementioning

confidence: 99%

Section: Aromatic Production Based On the Fts Routementioning

confidence: 99%

Advances in Selectivity Control for Fischer–Tropsch Synthesis to Fuels and Chemicals with High Carbon Efficiency

Lin

et al. 2022

ACS Catal.

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“…Generally, the synthesis methods of the Fe-based catalyst include CP, IWI, and SP methods; therefore, in order to compare the catalytic activity of different schemes, Fe-based catalysts with the same Mg and Zn contents were evaluated by CP and IWI methods, respectively. , Figure d shows that compared with CP and IWI, the catalyst made by the SP method shows a better catalytic effect of (97%) CO conversion, while the CO conversion rate of the catalyst prepared by the former two methods is similar, and the selectivity of the byproducts (CO 2 and CH 4 ) produced therewith is lower for CP. It could be interpreted that the SP method contributes to the formation of metal colloids, which makes the combination of Fe, Zn, and Mg stronger and more stable (to be discussed) .…”

Section: Resultsmentioning

confidence: 99%

“…The Na–FeZnMg catalyst was synthesized by the sol precipitation (SP) method with different Fe (NO 3 ) 3 ·9H 2 O, Mg (NO 3 ) 2 ·6H 2 O, and Zn (NO 3 ) 2 ·3H 2 O weight ratios dissolved into a beaker of 200 mL of water. , Then, slowly drop-by-drop pre-configured 1.5 mol/1000 mL NaOH precipitant was added into the beaker through a separatory funnel until the final pH reached 9, while being continuously stirred at a temperature of 70 °C. After the titration process, the mixture was allowed to stand for an aging time of 1 h at 70 °C.…”

Section: Experimental Partmentioning

confidence: 99%

“…The usage of a metal oxide/zeolite composite catalyst to directly convert syngas into aromatics in a single step has substituted the former method with its characteristics of fewer reaction steps, simple operation, and high economic efficiency . A vast range of methanol synthesis catalysts composited with HZSM-5 have been successfully investigated for the synthesis of aromatics from syngas, illustrating the higher aromatics selectivity; however, it shows a lower CO conversion rate with considerable byproducts and usually is prone to earlier catalyst deactivation. − As such, Fe-based metal oxides with high-temperature resistance and a broad range of (C 1 –C 60 ) hydrocarbon streams have become the focus of interest in recent years to be integrated with ZSM-5 for breaking the Anderson–Schulz–Flory distribution law of the Fischer–Tropsch synthesis (FTS) product and obtaining higher aromatics selectivity. − However, the poor chain growth ability, being prone to coke formation, and poisonous nature of these metallic systems at higher reaction temperatures direly need the addition of appropriate auxiliary components to play a vital role in adjusting the catalytic activity, selectivity, and stability. , Alkali metal promoters are famous electron donors that can greatly improve the dissociation ability of the C–O bond and promote the reduction and carbonization of iron oxides, leading to the active FeC x species. , Nevertheless, the competitive adsorption of CO and H 2 on the catalyst surface and the alkali migration phenomenon in the composite catalyst need the careful optimization of the added metal amount and other catalytic/process parameters. , …”

Section: Introductionmentioning

confidence: 99%

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Effective Inclusion of ZnMg in a Fe-Based/HZSM-5-Integrated Catalyst for the Direct Synthesis of Aromatics from Syngas

Saif

Nawaz

et al. 2022

Energy Fuels

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Being a significant raw material to numerous chemicals, aromatic hydrocarbons have been emerged as an advancing research platform in recent years, via the syngas to aromatics (STA) process. In the current study, a modified FeZnMg catalyst prepared by a sol-precipitation method was integrated with an HZSM-5 catalyst for the direct aromatic synthesis from syngas. Various catalytic/process parameters, including catalyst loading amount, precipitating pH, calcination/reduction/reaction T, space velocity, syngas ratio, reaction P, and reduction time, contributed toward the different synergism of the bimetallic Fe oxide nanoparticles. The significant electronic modulations induced upon the effective inclusion of Zn in a feasible parametric influence led to the generation of spinel (ZnFe 2 O 4 ) ferrite that eventually facilitated the reduction process of Fe oxide. While the enhanced dispersion of active sites and tuned Fe-lattice structures with Mg addition improved the carburization behavior of Fe species in response to the stronger C−O chemisorption, and thereby suppressed the excessive CO 2 and C 1 −C 4 paraffin generation. The originated synergistic interaction of bimetallic species in an appropriate catalytic environment of FeZnMg for accelerating the formation of Fe carbide, dictate the 52% aromatic selectivity at 97% CO conversion. While an excess in the Zn−Mg loading amount, pH, and calcination/reduction/reaction, T, can adversely affect the catalytic activity to varying degrees of the diminished active catalyst surface and inhibit CO adsorption.

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High‐Efficiency and Long‐life Synergetic Dual‐Oxide/Zeolite Catalyst for Direct Conversion of Syngas into Aromatics

et al. 2022

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Direct conversion of syngas to aromatics over metal oxidezeolite (OX-ZEO) composite catalysts is a novel route for efficient utilization of carbon resources. To realize a high activity with considerable selectivity to aromatics and stability, the design of synergetic OX-ZEO catalyst to meet complex kinetics still remains a great challenge. In this work, a synergetic dualoxide/zeolite catalyst was developed to tune the coupling between CO and H 2 activation through active H species migration, by adopting ZnZrO x oxide with stable single-layer ZnÀ O structure for H 2 activation and CeZrO x oxide with abundant oxygen vacancies as the CO activation component.The ratio and the proximity of CeZrO x and ZnZrO x is essential for the catalyst activity and stability. The optimal catalyst 1CeZrO x -2ZnZrO x /Z5@Si shows a superior catalytic performance with 75.6 % aromatics selectivity at a CO conversion as high as 57.5 %. After induction period, the catalyst exhibits excellent stability for 1100 h, keeping the high selectivity above 75 % with an average conversion of 43 %. This work will provide a new perspective to design a high performance and long-life OX-ZEO composite catalyst for direct conversion of syngas to high value chemicals.

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Harnessing the Synergistic Interplay of Fischer‐Tropsch Synthesis (Fe‐Co) Bimetallic Oxides in Na‐FeMnCo/HZSM‐5 Composite Catalyst for Syngas Conversion to Aromatic Hydrocarbons

Cited by 21 publications

References 58 publications

Advances in Selectivity Control for Fischer–Tropsch Synthesis to Fuels and Chemicals with High Carbon Efficiency

Advances in Selectivity Control for Fischer–Tropsch Synthesis to Fuels and Chemicals with High Carbon Efficiency

Effective Inclusion of ZnMg in a Fe-Based/HZSM-5-Integrated Catalyst for the Direct Synthesis of Aromatics from Syngas

High‐Efficiency and Long‐life Synergetic Dual‐Oxide/Zeolite Catalyst for Direct Conversion of Syngas into Aromatics

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