Search

Your search keyword '"Duyar, Melis S."' showing total 123 results
Start Over Author "Duyar, Melis S."
123 results on '"Duyar, Melis S."'

2. Contributors

Author

Afsharian, Yasamin Pesaran, primary, Arellano-García, H., additional, Arroyo, F., additional, Baena-Moreno, Francisco M., additional, Borrero, F. Vega, additional, Carrillo-Peña, D., additional, Castilla, Guillermo Martinez, additional, Centeno, Miguel A., additional, Charisiou, Nikolaos D., additional, Courard, L., additional, Ding, Yanqing, additional, Duyar, Melis S., additional, Fedeli, Matteo, additional, Fernández, C., additional, Gadkari, Siddharth, additional, Gallego-Fernández, Luz M., additional, Gao, Yunfei, additional, González-Arias, Judith, additional, González-Castaño, M., additional, Goula, Maria A., additional, Grigoletto, S., additional, Guío-Pérez, Diana Carolina, additional, He, Yulian, additional, Hua, Cheng, additional, Huang, Xu, additional, Ivanova, Svetlana, additional, Johnsson, Filip, additional, la Peña, N. Vidal-De, additional, León, E., additional, Léonard, G., additional, Manenti, Flavio, additional, Masoudi, Mahsa, additional, Mateos, R., additional, Merkouri, Loukia-Pantzechroula, additional, Montastruc, Ludovic, additional, Monzón, A., additional, Mur-Gorgas, A., additional, Navarrete, Benito, additional, Navarro, Juan Carlos, additional, Negri, Francesco, additional, Pallarès, David, additional, Pastor-Pérez, Laura, additional, Portillo, E., additional, Prieto, A., additional, Rahimnejad, Mostafa, additional, Ramírez-Reina, Tomás, additional, Rodríguez, M., additional, Ruíz-López, Estela, additional, Salvian, Anna, additional, Sebastia-Saez, Daniel, additional, Siakavelas, Georgios I., additional, Tarifa, P., additional, Toye, D., additional, Vilches, Luis F., additional, Yang, Liuqingqing, additional, and Zhang, Qi, additional

Published
2024
Full Text
View/download PDF

16. The Need for Flexible Chemical Synthesis and How Dual-Function Materials Can Pave the Way

Author

European Commission, Engineering and Physical Sciences Research Council (UK), Ministerio de Ciencia e Innovación (España), Paksoy, Aysun Ipek[0000-0002-8904-0409], Ramírez-Reina, Tomás[0000-0001-9693-5107], Duyar, Melis S[0000-0002-9891-5932], Merkouri, Loukia-Pantzechroula, Paksoy, Aysun Ipek, Ramírez-Reina, Tomás, Duyar, Melis S, European Commission, Engineering and Physical Sciences Research Council (UK), Ministerio de Ciencia e Innovación (España), Paksoy, Aysun Ipek[0000-0002-8904-0409], Ramírez-Reina, Tomás[0000-0001-9693-5107], Duyar, Melis S[0000-0002-9891-5932], Merkouri, Loukia-Pantzechroula, Paksoy, Aysun Ipek, Ramírez-Reina, Tomás, and Duyar, Melis S

Abstract

Since climate change keeps escalating, it is imperative that the increasing CO2 emissions be combated. Over recent years, research efforts have been aiming for the design and optimization of materials for CO2 capture and conversion to enable a circular economy. The uncertainties in the energy sector and the variations in supply and demand place an additional burden on the commercialization and implementation of these carbon capture and utilization technologies. Therefore, the scientific community needs to think out of the box if it is to find solutions to mitigate the effects of climate change. Flexible chemical synthesis can pave the way for tackling market uncertainties. The materials for flexible chemical synthesis function under a dynamic operation, and thus, they need to be studied as such. Dual-function materials are an emerging group of dynamic catalytic materials that integrate the CO2 capture and conversion steps. Hence, they can be used to allow some flexibility in the production of chemicals as a response to the changing energy sector. This Perspective highlights the necessity of flexible chemical synthesis by focusing on understanding the catalytic characteristics under a dynamic operation and by discussing the requirements for the optimization of materials at the nanoscale.

Published
2023

22. Engineering exsolved catalysts for CO2 conversion

Author

University of Surrey, Ramírez-Reina, Tomás[0000-0001-9693-5107], Ali, Swali A., Safi, Manzoor, Merkouri, Loukia Pantzechroula, Soodi, Sanaz, Iakovidis, Andreas, Duyar, Melis S., Neagu, Dragos, Ramírez-Reina, Tomás, Kousi, Kalliopi, University of Surrey, Ramírez-Reina, Tomás[0000-0001-9693-5107], Ali, Swali A., Safi, Manzoor, Merkouri, Loukia Pantzechroula, Soodi, Sanaz, Iakovidis, Andreas, Duyar, Melis S., Neagu, Dragos, Ramírez-Reina, Tomás, and Kousi, Kalliopi

Abstract

Introduction: Innovating technologies to efficiently reduce carbon dioxide (CO2) emission or covert it into useful products has never been more crucial in light of the urgent need to transition to a net-zero economy by 2050. The design of efficient catalysts that can make the above a viable solution is of essence. Many noble metal catalysts already display high activity, but are usually expensive. Thus, alternative methods for their production are necessary to ensure more efficient use of noble metals. Methods: Exsolution has been shown to be an approach to produce strained nanoparticles, stable against agglomeration while displaying enhanced activity. Here we explore the effect of a low level of substitution of Ni into a Rh based A-site deficienttitanate aiming to investigate the formation of more efficient, low loading noblemetal catalysts. Results: We find that with the addition of Ni in a Rh based titanate exsolution is increased by up to ∼4 times in terms of particle population which in turn results in up to 50% increase in its catalytic activity for CO2 conversion. Discussion: We show that this design principle not only fulfills a major research need in the conversion of CO2 but also provides a step-change advancement in the design and synthesis of tandem catalysts by the formation of distinct catalytically active sites.

Published
2023

23. Catalytic processes for fuels production from CO2-rich streams: Opportunities for industrial flue gases upgrading

Author

Merkouri, Loukia Pantzechroula, Zhang, Qi, Ramírez-Reina, Tomás, Duyar, Melis S., Merkouri, Loukia Pantzechroula, Zhang, Qi, Ramírez-Reina, Tomás, and Duyar, Melis S.

Abstract

Carbon dioxide (CO2) can be used as a C1 building block for the production of fuels and chemicals. The use of catalysts in the decarbonization of CO2-rich industries via the utilization of CO2 is fundamental. Herein, the aim of this chapter is to describe the catalytic upgrading of CO2-rich industrial flue gases. Initially, the CO2 capture technologies including precombustion, postcombustion, and oxyfuel are discussed. In addition, the industries producing CO2-rich streams which are cement, steel and iron, biogas, and brewery are described. Moreover, the effect of impurities during CO2 capture and conversion into high-value chemicals and fuels are examined. Finally, the reaction pathways during which CO2 is converted into added-value fuels and chemicals are explained by emphasizing the desirable catalytic characteristics and the current catalytic limitations.

Published
2023

24. Unravelling the CO2 capture and conversion mechanism of a NiRu-Na2O switchable dual-function material in various CO2 utilisation reactions

Author

European Commission, Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Bobadilla, Luis F.[0000-0003-0085-9811, Odriozola, José Antonio[0000-0002-8283-0459], Ramírez-Reina, Tomás[0000-0001-9693-5107], Merkouri, Loukia Pantzechroula, Martín-Espejo, Juan Luis, Bobadilla, Luis F., Odriozola, José Antonio, Penkova, Anna, Ramírez-Reina, Tomás, Duyar, Melis S., European Commission, Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Bobadilla, Luis F.[0000-0003-0085-9811, Odriozola, José Antonio[0000-0002-8283-0459], Ramírez-Reina, Tomás[0000-0001-9693-5107], Merkouri, Loukia Pantzechroula, Martín-Espejo, Juan Luis, Bobadilla, Luis F., Odriozola, José Antonio, Penkova, Anna, Ramírez-Reina, Tomás, and Duyar, Melis S.

Abstract

Time-resolved operando DRIFTS-MS was performed to elucidate the CO2 capture and conversion mechanisms of a NiRuNa/CeAl DFM in CO2 methanation, reverse water-gas shift, and dry reforming of methane. CO2 was captured mainly in the form of carbonyls and bidentate carbonates, and a spillover mechanism occurred to obtain the desired products.

Published
2023

25. Engineering Exsolved Catalysts for CO2 Conversion

Author

Universidad de Sevilla. Departamento de Química Inorgánica, Ali, Swali A., Safi, Manzoor, Merkouri, Loukia Pantzechroula, Soodi, Sanaz, Iakovidis, Andreas, Duyar, Melis S., Neagu, Dragos, Ramírez Reina, Tomás, Kousi, Kalliopi, Universidad de Sevilla. Departamento de Química Inorgánica, Ali, Swali A., Safi, Manzoor, Merkouri, Loukia Pantzechroula, Soodi, Sanaz, Iakovidis, Andreas, Duyar, Melis S., Neagu, Dragos, Ramírez Reina, Tomás, and Kousi, Kalliopi

Abstract

Introduction: Innovating technologies to efficiently reduce carbon dioxide (CO2) emission or covert it into useful products has never been more crucial in light of the urgent need to transition to a net-zero economy by 2050. The design of efficient catalysts that can make the above a viable solution is of essence. Many noble metal catalysts already display high activity, but are usually expensive. Thus, alternative methods for their production are necessary to ensure more efficient use of noble metals.Methods: Exsolution has been shown to be an approach to produce strained nanoparticles, stable against agglomeration while displaying enhanced activity. Here we explore the effect of a low level of substitution of Ni into a Rh based A-site deficienttitanate aiming to investigate the formation of more efficient, low loading noblemetal catalysts.Results: We find that with the addition of Ni in a Rh based titanate exsolution is increased by up to similar to 4 times in terms of particle population which in turn results in up to 50% increase in its catalytic activity for CO2 conversion.Discussion: We show that this design principle not only fulfills a major research need in the conversion of CO2 but also provides a step-change advancement in the design and synthesis of tandem catalysts by the formation of distinct catalytically active sites.

Published
2023

26. The Need for Flexible Chemical Synthesis and How Dual-Function Materials Can Pave the Way

Author

Universidad de Sevilla. Departamento de Química Inorgánica, University of Surrey. UK., European Union (UE). H2020, Ministerio de Ciencia e Innovación (MICIN). España, Merkouri, Loukia Pantzechroula, Paksoy, Aysun Ipek, Ramírez Reina, Tomás, Duyar, Melis S., Universidad de Sevilla. Departamento de Química Inorgánica, University of Surrey. UK., European Union (UE). H2020, Ministerio de Ciencia e Innovación (MICIN). España, Merkouri, Loukia Pantzechroula, Paksoy, Aysun Ipek, Ramírez Reina, Tomás, and Duyar, Melis S.

Abstract

Since climate change keeps escalating, it is imperative that the increasing CO2 emissions be combated. Over recent years, research efforts have been aiming for the design and optimization of materials for CO2 capture and conversion to enable a circular economy. The uncertainties in the energy sector and the variations in supply and demand place an additional burden on the commercialization and implementation of these carbon capture and utilization technologies. Therefore, the scientific community needs to think out of the box if it is to find solutions to mitigate the effects of climate change. Flexible chemical synthesis can pave the way for tackling market uncertainties. The materials for flexible chemical synthesis function under a dynamic operation, and thus, they need to be studied as such. Dual-function materials are an emerging group of dynamic catalytic materials that integrate the CO2 capture and conversion steps. Hence, they can be used to allow some flexibility in the production of chemicals as a response to the changing energy sector. This Perspective highlights the necessity of flexible chemical synthesis by focusing on understanding the catalytic characteristics under a dynamic operation and by discussing the requirements for the optimization of materials at the nanoscale.

Published
2023

27. Switchable catalysis for methanol and synthetic natural gas synthesis from CO2: A techno-economic investigation

Author

Universidad de Sevilla. Departamento de Química Inorgánica, Universidad de Sevilla. TEP106: Química de Superficies y Catálisis, School of Chemistry and Chemical Engineering, Doctoral College of the University of Surrey, Merkouri, Loukia Pantzechroula, Mathew, Jayson, Jacob, Jerin, Ramírez Reina, Tomás, Duyar, Melis S., Universidad de Sevilla. Departamento de Química Inorgánica, Universidad de Sevilla. TEP106: Química de Superficies y Catálisis, School of Chemistry and Chemical Engineering, Doctoral College of the University of Surrey, Merkouri, Loukia Pantzechroula, Mathew, Jayson, Jacob, Jerin, Ramírez Reina, Tomás, and Duyar, Melis S.

Abstract

The oil and gas sector produces a considerable volume of greenhouse gas emissions, mainly generated from flaring and venting natural gas. Herein, a techno-economic analysis has been performed of a switchable catalytic process to convert the CH4 and CO2 in flared/vented natural gas into syngas or methanol. Specifically, it was shown that depending on greenhouse gas composition, dry methane reforming (DRM), reverse water-gas shift (RWGS), and CO2 methanation could be chosen to valorise emissions in an overall profitable and flexible operation scenario. The switchable process produced methanol and synthetic natural gas as its products, resulting in an annual income of €687m and annual operating expenses of €452m. The pre-tax profit was calculated at €234m, and at the end of the project, the net present value was calculated as €1.9b with a profitability index of 4.7€/€. The expected payback time of this process was ca. 4 years, and with a 35% internal rate of return (IRR). Most importantly, this process consumed 42.8m tonnes of CO2 annually. The sensitivity analysis revealed that variations in operation time, green hydrogen price, and products’ prices significantly impacted the profitability of the process. Overall, this techno-economic analysis demonstrated that switchable catalysis in greenhouse gas utilisation processes is profitable, and thus it could play an important role in achieving net zero emissions.

Published
2023

29. Engineering exsolved catalysts for CO2 conversion

Author

Ali, Swali A., primary, Safi, Manzoor, additional, Merkouri, Loukia-Pantzechroula, additional, Soodi, Sanaz, additional, Iakovidis, Andreas, additional, Duyar, Melis S., additional, Neagu, Dragos, additional, Reina, Tomas Ramirez, additional, and Kousi, Kalliopi, additional

Published
2023
Full Text
View/download PDF

33. Unravelling the CO2 capture and conversion mechanism of a NiRu–Na2O switchable dual-function material in various CO2 utilisation reactions.

Author

Merkouri, Loukia-Pantzechroula, Martín-Espejo, Juan Luis, Bobadilla, Luis F., Odriozola, José Antonio, Penkova, Anna, Ramirez Reina, Tomas, and Duyar, Melis S.

Abstract

Time-resolved operando DRIFTS-MS was performed to elucidate the CO2 capture and conversion mechanisms of a NiRuNa/CeAl DFM in CO2 methanation, reverse water–gas shift, and dry reforming of methane. CO2 was captured mainly in the form of carbonyls and bidentate carbonates, and a spillover mechanism occurred to obtain the desired products. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

35. Ni-Phosphide catalysts as versatile systems for gas-phase CO2 conversion: Impact of the support and evidences of structure-sensitivity

Author

Universidad de Alicante. Departamento de Química Inorgánica, Universidad de Alicante. Instituto Universitario de Materiales, Zhang, Qi, Pastor Pérez, Laura, Villora-Picó, Juan José, Joyce, Miriam, Sepúlveda-Escribano, Antonio, Duyar, Melis S., Ramírez Reina, Tomás, Universidad de Alicante. Departamento de Química Inorgánica, Universidad de Alicante. Instituto Universitario de Materiales, Zhang, Qi, Pastor Pérez, Laura, Villora-Picó, Juan José, Joyce, Miriam, Sepúlveda-Escribano, Antonio, Duyar, Melis S., and Ramírez Reina, Tomás

Abstract

We report for the first time the support dependent activity and selectivity of Ni-rich nickel phosphide catalysts for CO2 hydrogenation. New catalysts for CO2 hydrogenation are needed to commercialise the reverse water–gas shift reaction (RWGS) which can feed captured carbon as feedstock for traditionally fossil fuel-based processes, as well as to develop flexible power-to-gas schemes that can synthesise chemicals on demand using surplus renewable energy and captured CO2. Here we show that Ni2P/SiO2 is a highly selective catalyst for RWGS, producing over 80% CO in the full temperature range of 350–750 °C. This indicates a high degree of suppression of the methanation reaction by phosphide formation, as Ni catalysts are known for their high methanation activity. This is shown to not simply be a site blocking effect, but to arise from the formation of a new more active site for RWGS. When supported on Al2O3 or CeAl, the dominant phase of as synthesized catalysts is Ni12P5. These Ni12P5 catalysts behave very differently compared to Ni2P/SiO2, and show activity for methanation at low temperatures with a switchover to RWGS at higher temperatures (reaching or approaching thermodynamic equilibrium behaviour). This switchable activity is interesting for applications where flexibility in distributed chemicals production from captured CO2 can be desirable. Both Ni12P5/Al2O3 and Ni12P5/CeAl show excellent stability over 100 h on stream, where they switch between methanation and RWGS reactions at 50–70% conversion. Catalysts are characterized before and after reactions via X-ray Diffraction (XRD), X-ray Photoelectron Spectroscopy (XPS), temperature-programmed reduction and oxidation (TPR, TPO), Transmission Electron Microscopy (TEM), and BET surface area measurement. After reaction, Ni2P/SiO2 shows the emergence of a crystalline Ni12P5 phase while Ni12P5/Al2O3 and Ni12P5/CeAl both show the crystalline Ni3P phase. While stable activity of the latter catalysts is demonstrated via

Published
2022

36. Ni-Phosphide catalysts as versatile systems for gas-phase CO2 conversion: Impact of the support and evidences of structure-sensitivity

Author

Universidad de Sevilla. Departamento de Química Inorgánica, University of Surrey, Royal Society Research, Ministerio de Ciencia e Innovación (MICIN). España, European Commission (EC), Zhang, Qiang, Pastor Pérez, Laura, Villora Pico, J. J., Joyce, M., Sepúlveda Escribano, Antonio, Duyar, Melis S., Ramírez Reina, Tomás, Universidad de Sevilla. Departamento de Química Inorgánica, University of Surrey, Royal Society Research, Ministerio de Ciencia e Innovación (MICIN). España, European Commission (EC), Zhang, Qiang, Pastor Pérez, Laura, Villora Pico, J. J., Joyce, M., Sepúlveda Escribano, Antonio, Duyar, Melis S., and Ramírez Reina, Tomás

Abstract

We report for the first time the support dependent activity and selectivity of Ni-rich nickel phosphide catalysts for CO2 hydrogenation. New catalysts for CO2 hydrogenation are needed to commercialise the reverse water–gas shift reaction (RWGS) which can feed captured carbon as feedstock for traditionally fossil fuel-based processes, as well as to develop flexible power-to-gas schemes that can synthesise chemicals on demand using surplus renewable energy and captured CO2. Here we show that Ni2P/SiO2 is a highly selective catalyst for RWGS, producing over 80% CO in the full temperature range of 350–750 °C. This indicates a high degree of suppression of the methanation reaction by phosphide formation, as Ni catalysts are known for their high methanation activity. This is shown to not simply be a site blocking effect, but to arise from the formation of a new more active site for RWGS. When supported on Al2O3 or CeAl, the dominant phase of as synthesized catalysts is Ni12P5. These Ni12P5 catalysts behave very differently compared to Ni2P/SiO2, and show activity for methanation at low temperatures with a switchover to RWGS at higher temperatures (reaching or approaching thermodynamic equilibrium behaviour). This switchable activity is interesting for applications where flexibility in distributed chemicals production from captured CO2 can be desirable. Both Ni12P5/Al2O3 and Ni12P5/CeAl show excellent stability over 100 h on stream, where they switch between methanation and RWGS reactions at 50–70% conversion. Catalysts are characterized before and after reactions via X-ray Diffraction (XRD), X-ray Photoelectron Spectroscopy (XPS), temperature-programmed reduction and oxidation (TPR, TPO), Transmission Electron Microscopy (TEM), and BET surface area measurement. After reaction, Ni2P/SiO2 shows the emergence of a crystalline Ni12P5 phase while Ni12P5/Al2O3 and Ni12P5/CeAl both show the crystalline Ni3P phase. While stable activity of the latter catalysts is demonstrated via

Published
2022

37. Versatile Ni-Ru catalysts for gas phase CO2 conversion: Bringing closer dry reforming, reverse water gas shift and methanation to enable end-products flexibility

Author

Universidad de Sevilla. Departamento de Química Inorgánica, Merkouri, Loukia Pantzechroula, Le Saché, Estelle, Pastor Pérez, Laura, Duyar, Melis S., Ramírez Reina, Tomás, Universidad de Sevilla. Departamento de Química Inorgánica, Merkouri, Loukia Pantzechroula, Le Saché, Estelle, Pastor Pérez, Laura, Duyar, Melis S., and Ramírez Reina, Tomás

Abstract

Advanced catalytic materials able to catalyse more than one reaction efficiently are needed within the CO2 utilisation schemes to benefit from end-products flexibility. In this study, the combination of Ni and Ru (15 and 1 wt%, respectively) was tested in three reactions, i.e. dry reforming of methane (DRM), reverse water–gas shift (RWGS) and CO2 methanation. A stability experiment with one cycle of CO2 methanation-RWGS-DRM was carried out. Outstanding stability was revealed for the CO2 hydrogenation reactions and as regards the DRM, coke formation started after 10 h on stream. Overall, this research showcases that a multicomponent Ni-Ru/CeO2-Al2O3 catalyst is an unprecedent versatile system for gas phase CO2 recycling. Beyond its excellent performance, our switchable catalyst allows a fine control of end-products selectivity.

Published
2022

38. Nanoreactor Engineering Can Unlock New Possibilities for CO2 Tandem Catalytic Conversion to CC Coupled Products.

Author

Goksu, Ali, Li, Haitao, Liu, Jian, and Duyar, Melis S.

Subjects
STRUCTURE-activity relationships, GREENHOUSE gases, CHEMICAL reduction, METHANOL as fuel, CARBON dioxide, ENGINEERING, FERTILITY clinics
Abstract

Climate change is becoming increasingly more pronounced every day while the amount of greenhouse gases in the atmosphere continues to rise. CO2 reduction to valuable chemicals is an approach that has gathered substantial attention as a means to recycle these gases. Herein, some of the tandem catalysis approaches that can be used to achieve the transformation of CO2 to CC coupled products are explored, focusing especially on tandem catalytic schemes where there is a big opportunity to improve performance by designing effective catalytic nanoreactors. Recent reviews have highlighted the technical challenges and opportunities for advancing tandem catalysis, especially highlighting the need for elucidating structure‐activity relationships and mechanisms of reaction through theoretical and in situ/operando characterization techniques. In this review, the focus is on nanoreactor synthesis strategies as a critical research direction, and discusses these in the context of two main tandem pathways (CO‐mediated pathway and Methanol‐mediated pathway) to CC coupled products. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

39. Design of mesoporous ZnCoSiOx hollow nanoreactors with specific spatial distribution of metal species for selective CO2 hydrogenation.

Author

Wang, Xinyao, Ye, Runping, Duyar, Melis S., Price, Cameron Alexander Hurd, Tian, Hao, Chen, Yanping, Ta, Na, Liu, Hao, and Liu, Jian

Abstract

In heterogeneous catalysis, the precise placement of active components to perform unique functions in cooperation with each other is a tremendous challenge. The migration of matter on micro/nano-scale caused by diffusion is a promising pathway for design of catalytic nanoreactors with precise active sites location and controllable microenvironment through compartmentalization and confinement effects. Herein, we report two categories of mesoporous ZnCoSiOx hollow nanoreactors with different metal distributions and microenvironment engineered by the diffusion behavior of metal species in confined nanospace. Double-shelled hollow structures with well-distributed metal species were obtained by adopting core@shell structured ZnCo-zeolitic imidazolate framework (ZIF)@SiO2 as a template and employing three stages of hydrothermal treatment including the decomposition of ZIF, diffusion of metal species into the silica shell, and Ostwald ripening. Additionally, the formation of yolk@shell structure with a collective (Zn-Co) metal oxide as the yolk was achieved by direct pyrolysis of ZnCo-ZIF@SiO2. In CO2 hydrogenation, ZnCoSiOx with double-shelled hollow structures and yolk@shell structures respectively afford CO and CH4 as main product, which is related with different dispersion and location of active sites in the two catalysts. This study provides an efficient method for the synthesis of catalytic nanoreactors on the basis of insights of the atomic diffusion in confined space at the mesoscale. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

45. Ni-Phosphide catalysts as versatile systems for gas-phase CO2 conversion: Impact of the support and evidences of structure-sensitivity

Author

Zhang, Qi, Pastor Pérez, Laura, Villora-Picó, Juan José, Joyce, Miriam, Sepúlveda-Escribano, Antonio, Duyar, Melis S., Ramírez Reina, Tomás, Universidad de Alicante. Departamento de Química Inorgánica, Universidad de Alicante. Instituto Universitario de Materiales, Materiales Avanzados, Universidad de Sevilla. Departamento de Química Inorgánica, University of Surrey, Royal Society Research, Ministerio de Ciencia e Innovación (MICIN). España, and European Commission (EC)

Subjects
Química Inorgánica, RWGS, Fuel Technology, General Chemical Engineering, Organic Chemistry, CO2 conversion, Methanation, Energy Engineering and Power Technology, Switchable Catalysts, Ni Phosphide
Abstract

We report for the first time the support dependent activity and selectivity of Ni-rich nickel phosphide catalysts for CO2 hydrogenation. New catalysts for CO2 hydrogenation are needed to commercialise the reverse water–gas shift reaction (RWGS) which can feed captured carbon as feedstock for traditionally fossil fuel-based processes, as well as to develop flexible power-to-gas schemes that can synthesise chemicals on demand using surplus renewable energy and captured CO2. Here we show that Ni2P/SiO2 is a highly selective catalyst for RWGS, producing over 80% CO in the full temperature range of 350–750 °C. This indicates a high degree of suppression of the methanation reaction by phosphide formation, as Ni catalysts are known for their high methanation activity. This is shown to not simply be a site blocking effect, but to arise from the formation of a new more active site for RWGS. When supported on Al2O3 or CeAl, the dominant phase of as synthesized catalysts is Ni12P5. These Ni12P5 catalysts behave very differently compared to Ni2P/SiO2, and show activity for methanation at low temperatures with a switchover to RWGS at higher temperatures (reaching or approaching thermodynamic equilibrium behaviour). This switchable activity is interesting for applications where flexibility in distributed chemicals production from captured CO2 can be desirable. Both Ni12P5/Al2O3 and Ni12P5/CeAl show excellent stability over 100 h on stream, where they switch between methanation and RWGS reactions at 50–70% conversion. Catalysts are characterized before and after reactions via X-ray Diffraction (XRD), X-ray Photoelectron Spectroscopy (XPS), temperature-programmed reduction and oxidation (TPR, TPO), Transmission Electron Microscopy (TEM), and BET surface area measurement. After reaction, Ni2P/SiO2 shows the emergence of a crystalline Ni12P5 phase while Ni12P5/Al2O3 and Ni12P5/CeAl both show the crystalline Ni3P phase. While stable activity of the latter catalysts is demonstrated via extended testing, this Ni enrichment in all phosphide catalysts shows the dynamic nature of the catalysts during operation. Moreover, it demonstrates that both the support and the phosphide phase play a key role in determining selectivity towards CO or CH4. Financial support for this work was provided by the Department of Chemical and Process Engineering at the University of Surrey and CO2ChemUK through the EPSRC grant EP/P026435/1 as well as the Royal Society Research Grant RSGR1180353. This work was also partially sponsored by Ministry of Science and Innovation through the projects PID2019-108453 GB-C21 and JC2019-040560-I. This work was also partially sponsored by the European Commission through the H2020-MSCA-RISE-2020 BIOALL project (Grant Agreement: 101008058. SASOL is also acknowledged for kindly providing the Al2O3-based supports.

Published
2022
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results