Tailoring Fe-Pt Composite Nanostructures through Iron Precursor Selection in Aqueous Low-Temperature Synthesis | Sciact - CRIS-system of Boreskov Institute of Catalysis

Tailoring Fe-Pt Composite Nanostructures through Iron Precursor Selection in Aqueous Low-Temperature Synthesis Full article

Journal

Journal of Composites Science
, E-ISSN: 2504-477X

Output data

Year: 2025, Volume: 9, Number: 11, Article number : 616, Pages count : 12 DOI: 10.3390/jcs9110616

Tags

Fe-Pt nanocomposites; iron precursor; low-temperature synthesis; phase evolution; biphasic materials; L12 intermetallic phase; structural characterization

Authors

Prigorodova Anna N. ¹ , Zakharov Nikita S. ¹ , Pugachev Valery M. ¹ , Shmakov Alexander N. ² , Adodin Nickolay S. ¹ , Russakov Dmitry M. ¹

Affiliations

1	Federal Research Center of Coal and Coal Chemistry SB RAS, Kemerovo 650099, Russia
2	Resource Sharing Center “The Siberian Circular Photon Source”, Koltsovo 630559, Russia

This study addresses the challenge of low-temperature synthesis of the high-performance L10 Fe-Pt intermetallic phase, which is critical for applications in ultra-high-density data storage and advanced magnetic devices. We demonstrate that the choice of iron precursor is a decisive factor in directing the phase composition and thermal evolution of Fe-Pt nanostructures, ultimately determining their suitability as functional composite materials. Fe-Pt systems were synthesized from aqueous solutions using platinum(IV) chloric acid (H2PtCl6) with either iron(III) ammonium sulfate (NH4Fe(SO4)2) or iron(II) sulfate (FeSO4). Comprehensive characterization using X-ray diffraction and high-resolution transmission electron microscopy revealed distinct composite formations. The iron(III) precursor yielded homogeneous, thermally stable nanocomposites: as-synthesized nanoparticles formed a Pt-based FCC solid solution (~5 nm), which upon annealing at 500 °C transformed into a biphasic nanocomposite of FCC solid solution and an L12 Fe21Pt79 intermetallic phase with minimal grain growth (~7 nm). In stark contrast, the system derived from iron(II) sulfate resulted in a heterogeneous composite of 4 nm Pt nanoparticles, an FCC solid solution, and discrete 1–3 nm Fe nanoparticles with L12-ordered FePt3 domains. Annealing this heterogeneous mixture caused phase segregation, forming significantly coarsened Pt-rich crystals (~30 nm) that were approximately 4–6 times larger than the crystallites in the annealed homogeneous composite, with negligible Fe incorporation. Our findings establish that precursor chemistry dictates the initial nanocomposite architecture, which in turn controls the pathway and success of low-temperature intermetallic phase formation. This work provides a crucial design principle for fabricating tailored Fe-Pt composite nanomaterials, moving beyond simple alloys to engineered multiphase systems for practical application.

Prigorodova A.N. , Zakharov N.S. , Pugachev V.M. , Shmakov A.N. , Adodin N.S. , Russakov D.M.
Tailoring Fe-Pt Composite Nanostructures through Iron Precursor Selection in Aqueous Low-Temperature Synthesis
Journal of Composites Science. 2025. V.9. N11. 616 :1-12. DOI: 10.3390/jcs9110616 WOS Scopus OpenAlex publication_identifier_short.sciact_skif_identifier_type

Submitted:	Sep 30, 2025
Accepted:	Nov 2, 2025
Published online:	Nov 8, 2025
Published print:	Nov 20, 2025

≡ Web of science:	WOS:001625692500001
≡ Scopus:	2-s2.0-105023120140
≡ OpenAlex:	W4416074904
≡ publication_identifier.sciact_skif_identifier_type:	4254

≡ Scopus	Нет цитирований	Сбор данных от 08.02.2026
≡ OpenAlex	Нет цитирований	Сбор данных от 08.02.2026