Abstract
340 ps observed and quantified localised jump diffusion within the frameworks of industrial acidic H-Y and H-Beta samples (Si/Al = 15 and 12.5 respectively), and methyl rotations which differed in rate between systems. As the zeolite pore diameter increased from H-Beta to H-Y, and as molecular size decreased from guaiacol to anisole, an increase in the proportion of diffusing molecules was observed by a factor of 2–3 across the temperature range. Faster rates of diffusion, longer jump distances, and expanded regions of confined diffusion were observed for the smaller anisole molecule in both frameworks and for both molecules in H-Y over H-Beta, indicating that the ratio between catalyst pore diameter and molecular size significantly affects local diffusivity in these catalysts. QENS observables generated from the MD simulations over the experimental timescale reproduced this confined diffusion, along with the trends in mobility with molecular size and framework topology. Upon probing an extended nanosecond timescale with the MD, anisole still diffused more quickly than guaiacol in both zeolites, and guaiacol diffused more quickly in H-Y than in H-Beta as per the localised motions. However, in contrast with experimentally observed/modelled localised motions, nanoscale diffusion of anisole was faster in H-Beta than in H-Y due to the straight channels of H-Beta facilitating continuous diffusion over the nanoscale, whereas in H-Y the diffusion rate beyond the confining region was slower due to the barriers to jumping between supercages. In addition to its larger molecular size, guaiacol’s hydroxyl group allowed for stronger interactions with the zeolite Brønsted acid sites than the methoxy group which both molecules possess, hindering diffusion further. The study highlights the complex interplay between molecular shape, functionality, steric pore hindrance and acid site interactions on the local and nanoscale mobility of important derivatives of lignin in potential catalysts for their conversion to fuels and useful chemicals.
Original language | English |
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Article number | 113388 |
Journal | Microporous and Mesoporous Materials |
Volume | 383 |
Early online date | 10 Nov 2024 |
DOIs | |
Publication status | E-pub ahead of print - 10 Nov 2024 |
Data Availability Statement
Data available as DOI from ILL database, as stated in Full Article.Funding
This work was supported by the UK Engineering and Physical Sciences Research Council (EPSRC) grant EP/R513155/1 for the University of Bath and as part of a studentship with the STFC. We thank the Institut Laue-Langevin (ILL), Grenoble, France, for beam-time allocation on the IN16B instrument (data available at doi:10.5291/ILL-DATA.7-05-582). The facilities at the ISIS Neutron and Muon Source were used for sample preparation. We also thank the ISIS Hydrogen and Catalysis Laboratory and Materials Characterisation Laboratory for preliminary sample characterisation. The authors thank the Computing resources provided by the STFC Scientific Computing Department's SCARF cluster. A. J. O'Malley acknowledges Roger and Sue Whorrod for the funding of a Whorrod Fellowship and IChemE for the provision of the Andrew Fellowship. C. L. M. Woodward acknowledges IChemE for the provision of the Andrew Studentship. The resources and support provided by the UK Catalysis Hub via membership of the UK Catalysis Hub consortium are gratefully acknowledged. This work was supported by the UK Engineering and Physical Sciences Research Council (EPSRC) grant EP/R513155/1 for the University of Bath and as part of a studentship with the STFC. We thank the Institut Laue-Langevin (ILL), Grenoble, France, for beam-time allocation on the IN16B instrument (data available at doi:10.5291/ILL-DATA.7-05-582). The facilities at the ISIS Neutron and Muon Source were used for sample preparation. We also thank the ISIS Hydrogen and Catalysis Laboratory and Materials Characterisation Laboratory for preliminary sample characterisation. The authors thank the Computing resources provided by the STFC Scientific Computing Department\u2019s SCARF cluster. A. J. O\u2019Malley acknowledges Roger and Sue Whorrod for the funding of a Whorrod Fellowship. The resources and support provided by the UK Catalysis Hub via membership of the UK Catalysis Hub consortium are gratefully acknowledged.
Funders | Funder number |
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ISIS Hydrogen and Catalysis Laboratory and Materials Characterisation Laboratory | |
Science and Technology Facilities Council | |
University of Bath | |
Institut Laue-Langevin | |
UK Catalysis Hub | |
Engineering and Physical Sciences Research Council | EP/R513155/1 |
Engineering and Physical Sciences Research Council |
Keywords
- Biomass
- Diffusion
- Dynamics
- Lignin
- Molecular dynamics
- Quasielastic neutron scattering
- Zeolites
ASJC Scopus subject areas
- General Chemistry
- General Materials Science
- Condensed Matter Physics
- Mechanics of Materials