Summary
The methanol-to-hydrocarbon (MTH) process is a versatile catalytic process that are gradually playing a more important role in the economy. However, an important factor that is inhibiting the profitability of MTH is accumulation of coke in the pores of the catalyst during operations. To reduce or eliminate the coke formation during MTH operations, it is necessary to have a detailed mechanistic insight into its cause of formation. In this proposal, I will achieve this insight through a computational modelling strategy. I will study the mechanism of the MTH process at various time- and length scales, using various computational methodologies. I will use computational fluid dynamics (CFD) to study the fluid flow at the reactor scale and the diffusion in the macropores. I will use kinetic Monte Carlo (kMC) and molecular dynamics (MD) to study the diffusion in the meso- and micropores. Finally, I will use density functional theory (DFT) to study the reactions at the active sites. The processes studied at the various length scales will be coupled together through a multiscale methodology.
Multiscale modelling has steadily evolved over the past decade, but the concept is still at the proof-of-principle stage where the methodology has been demonstrated for simple test systems such as CO oxidation. The methodologies that will provide data to the multiscale simulation, CFD, kMC, MD, and DFT have all reached a high level of maturity. Now is the right moment to use a multiscale methodology to couple these methodologies together and solve the problem of coke formation in the MTH process.
The potential outcomes are the following: 1) an understanding of how coke is formed in the MTH process; 2) a larger acceptance in the catalysis community to use multiscale modelling in the design of new catalysts; and 3) tighter interdisciplinary collaborations.
Multiscale modelling has steadily evolved over the past decade, but the concept is still at the proof-of-principle stage where the methodology has been demonstrated for simple test systems such as CO oxidation. The methodologies that will provide data to the multiscale simulation, CFD, kMC, MD, and DFT have all reached a high level of maturity. Now is the right moment to use a multiscale methodology to couple these methodologies together and solve the problem of coke formation in the MTH process.
The potential outcomes are the following: 1) an understanding of how coke is formed in the MTH process; 2) a larger acceptance in the catalysis community to use multiscale modelling in the design of new catalysts; and 3) tighter interdisciplinary collaborations.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/839376 |
| Start date: | 01-11-2019 |
| End date: | 31-10-2021 |
| Total budget - Public funding: | 171 473,28 Euro - 171 473,00 Euro |
Cordis data
Original description
The methanol-to-hydrocarbon (MTH) process is a versatile catalytic process that are gradually playing a more important role in the economy. However, an important factor that is inhibiting the profitability of MTH is accumulation of coke in the pores of the catalyst during operations. To reduce or eliminate the coke formation during MTH operations, it is necessary to have a detailed mechanistic insight into its cause of formation. In this proposal, I will achieve this insight through a computational modelling strategy. I will study the mechanism of the MTH process at various time- and length scales, using various computational methodologies. I will use computational fluid dynamics (CFD) to study the fluid flow at the reactor scale and the diffusion in the macropores. I will use kinetic Monte Carlo (kMC) and molecular dynamics (MD) to study the diffusion in the meso- and micropores. Finally, I will use density functional theory (DFT) to study the reactions at the active sites. The processes studied at the various length scales will be coupled together through a multiscale methodology.Multiscale modelling has steadily evolved over the past decade, but the concept is still at the proof-of-principle stage where the methodology has been demonstrated for simple test systems such as CO oxidation. The methodologies that will provide data to the multiscale simulation, CFD, kMC, MD, and DFT have all reached a high level of maturity. Now is the right moment to use a multiscale methodology to couple these methodologies together and solve the problem of coke formation in the MTH process.
The potential outcomes are the following: 1) an understanding of how coke is formed in the MTH process; 2) a larger acceptance in the catalysis community to use multiscale modelling in the design of new catalysts; and 3) tighter interdisciplinary collaborations.
Status
CLOSEDCall topic
MSCA-IF-2018Update Date
28-04-2024
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