Thermogravimetry in a Gradient Magnetic Field for Studying Magnetic Phase Formation

Thermogravimetry in a Gradient Magnetic Field for Studying Magnetic Phase Formation

August 1, 2025

This research presents a groundbreaking methodology for semi-quantitative analysis of magnetic phase composition during thermogravimetry in a gradient magnetic field (MTGA), specifically in cycling mode. The approach is demonstrated using Fe–Si–O xerogels, where various magnetic iron(III) oxide polymorphs (e-, g-, a-Fe2O3\mathrm{Fe}_2\mathrm{O}_3) can coexist and transform into each other.

The Challenge

Traditional methods for analyzing magnetic phase composition often face limitations:

  • Limited sensitivity to nanoscale phases
  • High cost and complexity of synchrotron-based techniques
  • Difficulty in distinguishing structurally similar phases
  • Time-consuming and resource-intensive procedures

These challenges hinder the efficient optimization of magnetic material synthesis processes.

Innovation: MTGA Methodology

The researchers developed a novel approach using:

  • Thermogravimetry in a gradient magnetic field (MTGA)
  • Cycling mode for quasi-in situ monitoring
  • Semi-quantitative phase analysis through weight change measurements
  • Mathematical modeling for phase composition estimation

This technique enables direct detection of magnetic transitions and provides excellent sensitivity to e-Fe2_2O3_3 and g-Fe2_2O3_3 phases, which is crucial for producing magnetically hard samples.

Key Results

  • Enhanced Sensitivity: MTGA exhibits significantly higher sensitivity to e-Fe2_2O3_3 and g-Fe2_2O3_3 phases compared to conventional methods
  • Optimized Synthesis Conditions: The method enables rapid optimization of heat treatment protocols for synthesizing pure e-Fe2_2O3_3
  • Phase Composition Control: Allows precise determination of phase fractions in complex mixtures
  • Efficiency: Processing 97 samples in quasi-in situ manner over 580 hours, compared to 3x longer with traditional XRD approaches

Technical Details

The study focused on Fe–Si–O xerogel system where:

  • Various magnetic iron(III) oxide polymorphs crystallize as nanoparticles during heat treatment
  • Three main phases exist: e-Fe2_2O3_3, g-Fe2_2O3_3, and a-Fe2_2O3_3
  • Each phase exhibits distinct Neél temperatures (approximately 490 K, 850 K, and 960 K, respectively)
  • The method uses a mathematical model to convert weight changes into mass fractions of individual magnetic phases

Impact

This advancement opens new possibilities for:

  • Rapid optimization of magnetic material synthesis
  • Quasi-in situ monitoring of phase transformations
  • Cost-effective alternative to expensive synchrotron techniques
  • Better understanding of magnetic phase behavior in nanomaterials
  • Improved control of solid-state reactions in magnetic systems

The study demonstrates that MTGA can overcome traditional limitations in magnetic phase analysis, providing a valuable tool for materials research and development.


Cite this work

@article{Gorbachev2025MagneticPhase,
  title={Thermogravimetry in a gradient magnetic field as an efficient quasiin situ method for studying magnetic phase formation: optimizing e-Fe$_2$O$_3$ synthesis},
  author={Gorbachev, E. A. and Wang, Y. and Duan, J. and Nygaard, R. R. and Kozlyakova, E. S. and Trusov, L. A.},
  journal={Materials Horizons},
  year={2025},
  volume={12},
  pages={9185--9197},
  doi={10.1039/d5mh01134e}
}