4.7 Article

The significant role of montmorillonite on the formation of hematite nanoparticles from ferrihydrite under heat treatment

Journal

APPLIED CLAY SCIENCE
Volume 202, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.clay.2020.105962

Keywords

Mineral nanoparticles; Ferrihydrite; Montmorillonite; Hematite; Heat treatment; Size

Funding

  1. National Natural Science Foundation of China [41872044, 41902040]
  2. Youth Innovation Promotion Association CAS [2020347]
  3. CAS Interdisciplinary Innovation Team [JCTD-2019-15]
  4. Science and Technology Planning of Guangdong Province [2020B1212060055]

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The study found that under high temperature conditions, montmorillonite has a positive impact on the transformation of ferrihydrite into hematite nanoparticles, dispersing particles and reducing their size. Strong interactions between montmorillonite and ferrihydrite can reduce aggregation, contributing to the understanding of the formation and preservation of natural nano-sized minerals in nature.
With high surface reactivity and weak crystallinity, ferrihydrite (Fh) tends to be transformed to other thermodynamically stable iron (hydr)oxides, and its transformation is strongly influenced by the coexisting substances. Clay minerals widely coexist with Fh in the near-surface areas, but there is limited information about their effects on the transformation of Fh. In this work, the effect of montmorillonite (Mt) on the formation of hematite (Hem) nanoparticles from Fh under heat treatment was studied. Fh, Mt, and their mixed samples (Fh-Mt) were heated at different temperatures (350, 450, 600, 700, and 800 degrees C) for various times (3, 5, and 10 h), and the samples before and after heating were well characterized. X-ray diffraction and Fe-57 Mossbauer spectroscopy results revealed that Fh was transformed to Hem after heat treatment in both the presence and absence of Mt. Scanning electron microscopy and transmission electron microscopy images indicated that Mt could well disperse Fh and distinctly decrease the particle sizes of the formed Hem after heating. In particular, the particle size of Hem reached similar to 1000 nm in the pure Fh system, while it was only 15-75 nm in the systems containing Mt. Fourier transform infrared spectroscopy patterns displayed the strong interactions between Mt and Fh (through the formation of Si-O-Fe and Al-O-Fe bonds), which may also reduce the aggregation of Fh and inhibit the phase transformation of Fh particles into large Hem particles. This work verifies the important protective effect of clay minerals on coexisting iron oxide under high-temperature conditions, which would contribute to better understanding the formation and preservation of natural nano-sized minerals (particles) in nature.

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