Nanomaterials (Jul 2021)

Elucidation of the Crystal Growth Characteristics of SnO<sub>2</sub> Nanoaggregates Formed by Sequential Low-Temperature Sol-Gel Reaction and Freeze Drying

  • Saeid Vafaei,
  • Alexander Wolosz,
  • Catlin Ethridge,
  • Udo Schnupf,
  • Nagisa Hattori,
  • Takashi Sugiura,
  • Kazuhiro Manseki

DOI
https://doi.org/10.3390/nano11071738
Journal volume & issue
Vol. 11, no. 7
p. 1738

Abstract

Read online

SnO2 nanoparticles are regarded as attractive, functional materials because of their versatile applications. SnO2 nanoaggregates with single-nanometer-scale lumpy surfaces provide opportunities to enhance hetero-material interfacial areas, leading to the performance improvement of materials and devices. For the first time, we demonstrate that SnO2 nanoaggregates with oxygen vacancies can be produced by a simple, low-temperature sol-gel approach combined with freeze-drying. We characterize the initiation of the low-temperature crystal growth of the obtained SnO2 nanoaggregates using high-resolution transmission electron microscopy (HRTEM). The results indicate that Sn (II) hydroxide precursors are converted into submicrometer-scale nanoaggregates consisting of uniform SnO2 spherical nanocrystals (2~5 nm in size). As the sol-gel reaction time increases, further crystallization is observed through the neighboring particles in a confined part of the aggregates, while the specific surface areas of the SnO2 samples increase concomitantly. In addition, X-ray photoelectron spectroscopy (XPS) measurements suggest that Sn (II) ions exist in the SnO2 samples when the reactions are stopped after a short time or when a relatively high concentration of Sn (II) is involved in the corresponding sol-gel reactions. Understanding this low-temperature growth of 3D SnO2 will provide new avenues for developing and producing high-performance, photofunctional nanomaterials via a cost-effective and scalable method.

Keywords