Teitl:    Quasielastic Neutron Scattering and Molecular Dynamics Simulation Study on the Molecular Behaviour of Catechol in Zeolite Beta - data

Dyfyniad
Hernandez-Tamargo C, Silverwood IP, O’Malley AJ, et al.  (2020). Quasielastic Neutron Scattering and Molecular Dynamics Simulation Study on the Molecular Behaviour of Catechol in Zeolite Beta - data. Cardiff University. https://doi.org/10.17035/d.2020.0120956733

Manylion y Set Ddata

Cyhoeddwr: Cardiff University

Dyddiad (y flwyddyn) pryd y daeth y data ar gael i'r cyhoedd: 2020

Dyddiad dechrau creu'r data: 01.11.2017

Dyddiad gorffen creu'r data: 31.08.2020

Fformat y data: txt, xls

Amcangyfrif o gyfanswm maint storio'r set ddata: Llai na 100 megabeit

DOI : 10.17035/d.2020.0120956733

DOI URL: http://doi.org/10.17035/d.2020.0120956733

Related URL: https://data.isis.stfc.ac.uk/doi/INVESTIGATION/87772570/

Disgrifiad

The dynamics of catechol in zeolite Beta was studied using quesielastic neutron scattering (QENS) experiments and molecular dynamics simulations at 393 K, to understand the behaviour of phenolic monomers relevant in the catalytic conversion of lignin via metal nanoparticles supported on zeolites. Compared to previous work studying phenol, both methods observe that the presence of the second OH group in catechol can hinder mobility significantly, as explained by stronger hydrogen-bonding interactions between catechol and the Brønsted sites of the zeolite. The instrumental timescale of the QENS experiment allows us to probe rotational motion, and the catechol motions are best fit to an isotropic rotation model with a Drot of 2.9·1010 s−1. While this Drot is within error of that measured for phenol, the fraction of molecules immobile on the instrumental timescale is found to be significantly higher for catechol. The MD simulations also exhibit this increased ‘immobility’, showing that long-range translational diffusion coefficients of catechol are lower than phenol by a factor of 7 in acidic zeolite Beta, and a factor of ∼3 in the siliceous material, further illustrating the significance of Brønsted site H-bonding. Upon reproducing QENS observables from our simulations to probe rotational motions, a combination of two isotropic rotations was found to fit the MD-calculated EISF; one corresponds to the free rotation of catechol in the pore system of the zeolite, while the second rotation is used to approximate a restricted and rapid "rattling" consistent with molecules anchored to the acid sites through their OH groups, the motion of which is too rapid to be observed by experiment.

Researhc results based upon these data are published at http://doi.org/10.1007/s11244-020-01400-1