Elucidation of the Nano-sized Molecular Structure of Methylaluminoxane using Synchrotron X-ray Total Scattering

05 December 2024, Version 2
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Methylaluminoxane (MAO) is commonly employed to activate molecular pre-catalysts in polyolefin synthesis, both indus-trially and in the laboratory. Despite the extensive use of this compound, the ambiguity related to its structure hampers the understanding of its structure–function relationship. The current study therefore employed synchrotron X-ray total scattering to elucidate the nano-sized molecular structure of MAO. The MAO samples, which were prepared using various synthetic protocols, exhibited consistent X-ray scattering patterns and atomic pair distribution function curves, indicating similar molecular structures. However, the scattering intensity in the small-angle region revealed differences in the high-er-order structures. A fitting study performed using 172 molecular models showed that small molecule and tube models were inadequate to reproduce the experimental results, whereas cage and sheet models provided comparably better fits. The sheet model was found to be consistent with the observed molecular weight and the molecular weight distribution, in addition to accounting for the intensity in the small-angle scattering region. These results align with recent crystallo-graphic findings reported in Science, where a stacked sheet model successfully reproduced an experimental X-ray dif-fraction pattern. Ultimately, determination of the structural motif of MAO is expected to be beneficial to systematic re-search and development using this compound.

Keywords

Methylaluminoxane
X-ray total scattering
Nanostructures
Atomic pair distribution function

Supplementary materials

Title
Description
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Title
Supporting information for fitting studies, graphical explanations, and a molecular model
Description
Simulated atomic pair distribution function (PDF) curves for molecular models optimized with various calculation methods; parameter distributions for PDF curve fitting; influence of Debye-Waller factors on simulation for X-ray scattering patterns and PDF curves; distributions of Al–Al distances in selected molecular models; examples of PDF curve fitting results; graphical explanations supporting the discussions in the main text; atomic configurations of a DFT-optimized molecular model
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