Cubes to Cubes: Organization of MgO Particles into One-Dimensional and Two-Dimensional Nanostructures.

Daniel Thomele,Ryan M Richards,Johannes Schneider,Gregor A Zickler,Gilles R Bourret,Thomas Schwab,Sarah Shulda,Stefan O Baumann,Andreas K Sternig,Oliver Diwald

doi:10.1021/acs.cgd.1c00535

Daniel Thomele, Ryan M Richards + Show 8 more

Open Access

https://doi.org/10.1021/acs.cgd.1c00535

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Abstract

Developing simple, inexpensive, and environmentally benign approaches to integrate morphologically well-defined nanoscale building blocks into larger high surface area materials is a key challenge in materials design and processing. In this work, we investigate the fundamental surface phenomena between MgO and water (both adsorption and desorption) with particles prepared via a vapor-phase process (MgO nanocubes) and a modified aerogel process (MgO(111) nanosheets). Through these studies, we unravel a strategy to assemble individual MgO nanoparticles into extended faceted single-crystalline MgO nanosheets and nanorods with well-defined exposed surfaces and edges. This reorganization can be triggered by the presence of H2O vapor or bulk liquid water. Water adsorption and the progressive conversion of vapor-phase grown oxide particles into hydroxides give rise to either one-dimensional or two-dimensional (1D or 2D) structures of high dispersion and surface area. The resulting Mg(OH)2 lamella with a predominant (001) surface termination are well-suited precursor structures for their topotactic conversion into laterally extended and uniform MgO(111) grain surface configurations. To understand the potential of polar (111) surfaces for faceting and surface reconstruction effects associated with water desorption, we investigated the stability of MgO(111) nanosheets during vacuum annealing and electron beam exposure. The significant surface reconstruction of the MgO(111) surfaces observed shows that adsorbate-free (111)-terminated surfaces of unsupported MgO nanostructures reconstruct rather than remain as charged planes of either three-fold coordinated O2– ion or Mg2+ ions. Thus, here we demonstrate the role water can play in surface formation and reconstruction by bridging wet chemical and surface science inspired approaches.

Highlights

It is well established that the size, shape, and faceting of metal oxide particles have a substantial impact on their catalytic activity as well as their chemical properties when utilized as catalyst supports
The water vapor exposure was performed in a pre-evacuated closed system that guaranteed the exclusion of CO2, O2, and other impurities from the gas phase that may affect the dissolution−
This study reports on the different steps involved in these transformations and demonstrates the following:

Summary

Introduction

It is well established that the size, shape, and faceting of metal oxide particles have a substantial impact on their catalytic activity as well as their chemical properties when utilized as catalyst supports. As a result of their simple morphology and the limited number of characteristic local surface structures, cubic metal oxide particles with a rock salt structure (such as MgO, CaO, CoO, MnO, NiO, and FeO) represent well-suited model compounds to study such phenomena. This is especially true for MgO particles produced by gas phase synthesis techniques such as chemical vapor synthesis (CVS),[6] flame spray pyrolysis (FSP),[7] or the combustion of metallic magnesium in air.[6] When these MgO particles are synthesized at high temperatures and in Received: May 7, 2021 Revised: June 22, 2021 Published: July 2, 2021

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