Researchers at the Institute of Science Tokyo have unveiled a pioneering method to synthesize advanced negative thermal expansion (NTE) materials, particularly the perovskite oxide BiNi₁₋ₓFeₓO₃, via a safer and more efficient process. This innovative approach leverages simultaneous coprecipitation and oxidation techniques to generate highly oxidized amorphous precursors, overcoming traditional manufacturing hurdles that often involve hazardous chemicals and environmentally harmful byproducts.
Functional oxides with high-valent metal ions are integral to many cutting-edge technologies, offering properties such as superconductivity, magnetism, and NTE—where materials contract upon heating rather than expanding. However, stabilizing such high oxidation states traditionally requires strong oxidizing agents and complex procedures that pose risks and limit scalability. The newly developed strategy addresses these challenges by simplifying synthesis while reducing environmental impact.
Led by Assistant Professor Takumi Nishikubo and collaborators, the team introduced a single-step process combining reverse coprecipitation with oxidation. By injecting metal nitrate solutions into an alkaline sodium hypochlorite medium, they achieved amorphous precursors rich in Bi⁵⁺ and Ni³⁺ ions, characterized by excellent elemental uniformity. This eliminates the need for conventional oxidants and prevents the release of nitrogen oxides (NOₓ), thus enhancing safety and sustainability.
Further examination using in situ synchrotron diffraction revealed that these precursors crystallize directly into the desired perovskite phase under high pressure at significantly lower temperatures (around 750 °C) and in a markedly reduced time span—less than one minute. This contrasts sharply with standard methods that require temperatures near 950 °C and pass through multiple intermediate phases, highlighting the efficiency and precision the novel method offers.
Beyond mere synthesis, the approach enables precise control over particle size, which has direct implications for material performance. By minimizing heat exposure, particle sizes were effectively reduced from 15 μm to 5 μm without compromising the NTE functionality. This size refinement also contributed to enhanced thermal stability across broader temperature ranges, signaling improved usability for practical applications.
Notably, the team demonstrated that this highly oxidized precursor strategy could extend to other functional oxides, including Cu³⁺-based superconducting materials. This broad applicability suggests a transformative impact on the production of various advanced oxides critical to electronics, energy, and thermal management technologies.
These findings mark a significant step toward greener and more controllable fabrication of complex oxide materials. By coupling safer chemical processes with faster, more controlled synthesis routes, the research not only advances the field of materials science but also aligns with growing industrial demands for sustainable manufacturing practices.
As industries increasingly seek materials with tailored thermal and electronic properties, this breakthrough offers a promising pathway that balances technological performance with environmental responsibility, potentially ushering in a new era of innovative oxide materials.
Subject of Research: Not applicable
Article Title: Synthesis of Unusually High Valent Perovskite Oxide from the Highly Oxidized Coprecipitation Precursor
News Publication Date: 18-Jun-2026
Web References: https://doi.org/10.1021/jacs.6c04051
Image Credits: Institute of Science Tokyo
Keywords: materials science, perovskites, negative thermal expansion, thermal properties, high-valent metal ions, coprecipitation, oxidation, advanced oxides, energy technologies
Tags: advanced synthesis of NTE materialsamorphous precursor synthesiseco-friendly negative thermal expansion materialsenvironmentally sustainable materials sciencehigh oxidation state stabilization in functional materialshigh-performance functional oxideshigh-valent metal ion stabilizationin situ synchrotron diffraction analysisperovskite oxide BiNi₁₋ₓFeₓO₃reverse coprecipitation and oxidation techniquessafer chemical manufacturing processesscalable green synthesis methods



