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高压合成的具有Fe-N和Fe-C核以及碳壳的磁性纳米颗粒

Magnetic Nanoparticles with Fe-N and Fe-C Cores and Carbon Shells Synthesized at High Pressures.

作者信息

Bagramov Rustem H, Filonenko Vladimir P, Zibrov Igor P, Skryleva Elena A, Kulnitskiy Boris A, Blank Vladimir D, Khabashesku Valery N

机构信息

Vereshchagin Institute of High Pressure Physics, Russian Academy of Sciences, Troitsk, Moscow 108840, Russia.

Department of Materials Science of Semiconductors and Dielectrics, National University of Science and Technology MISiS, Moscow 119049, Russia.

出版信息

Materials (Basel). 2023 Nov 7;16(22):7063. doi: 10.3390/ma16227063.

DOI:10.3390/ma16227063
PMID:38004993
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10672696/
Abstract

Nanoparticles of iron carbides and nitrides enclosed in graphite shells were obtained at 2 ÷ 8 GPa pressures and temperatures of around 800 °C from ferrocene and ferrocene-melamine mixture. The average core-shell particle size was below 60 nm. The graphite-like shells over the iron nitride cores were built of concentric graphene layers packed in a rhombohedral shape. It was found that at a pressure of 4 GPa and temperature of 800 °C, the stability of the nanoscale phases increases in a FeC -> FeC -> FeN sequence and at 8 GPa in a FeC -> FeC -> FeN sequence. At pressures of 2 ÷ 8 GPa and temperatures up to 1600 °C, iron nitride FeN is more stable than iron carbides. At 8 GPa and 1600 °C, the average particle size of iron nitride increased to 0.5 ÷ 1 μm, while simultaneously formed free carbon particles had the shape of graphite discs with a size of 1 ÷ 2 μm. Structural refinement of the iron nitride using the Rietveld method gave the best result for the space group P622. The refined composition of the samples obtained from a mixture of ferrocene and melamine at 8 GPa/800 °C corresponded to FeN, and at 8 GPa/1650 °C to FeN. The iron nitride core-shell nanoparticles exhibited magnetic behavior. Specific magnetization at 7.5 kOe of pure FeN was estimated to be 70 emu/g. Compared to other methods, the high-pressure method allows easy synthesis of the iron nitride cores inside pure carbon shells and control of the particle size. And in general, pressure is a good tool for modifying the phase and chemical composition of the iron-containing cores.

摘要

在2至8吉帕的压力和800℃左右的温度下,由二茂铁和二茂铁 - 三聚氰胺混合物制得包裹在石墨壳中的碳化铁和氮化铁纳米颗粒。核壳颗粒的平均尺寸小于60纳米。氮化铁核上的类石墨壳由以菱形堆积的同心石墨烯层构成。研究发现,在4吉帕的压力和800℃的温度下,纳米级相的稳定性按FeC -> FeC -> FeN的顺序增加,而在8吉帕时按FeC -> FeC -> FeN的顺序增加。在2至8吉帕的压力和高达1600℃的温度下,氮化铁FeN比碳化铁更稳定。在8吉帕和1600℃时,氮化铁的平均粒径增加到0.5至1微米,同时形成的游离碳颗粒呈尺寸为1至2微米的石墨盘形状。使用Rietveld方法对氮化铁进行结构精修,对于空间群P622得到了最佳结果。从二茂铁和三聚氰胺的混合物在8吉帕/800℃下获得的样品的精修组成对应于FeN,而在8吉帕/1650℃下对应于FeN。氮化铁核壳纳米颗粒表现出磁性行为。纯FeN在7.5千奥斯特下的比磁化强度估计为70emu/g。与其他方法相比,高压法允许在纯碳壳内轻松合成氮化铁核并控制粒径。一般而言,压力是改变含铁核的相和化学成分的良好工具。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/af28/10672696/b6894dcda69e/materials-16-07063-g010.jpg
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本文引用的文献

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Phase Stability of Iron Nitride FeN at High Pressure-Pressure-Dependent Evolution of Phase Equilibria in the Fe-N System.氮化铁FeN在高压下的相稳定性——铁氮体系中相平衡随压力的演变
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