Anomalous stepped-hysteresis and T-induced unit-cell-volume reduction in carbon nanotubes continuously filled with faceted Fe3C nanowires

Ferromagnetically-filled carbon nanotubes have been recently considered important candidates for application into data recording quantum disk devices. Achievement of high filling rates of the ferromagnetic materials is particularly desirable for applications. Here we report the novel observation of carbon nanotubes continuously filled along the capillary with unusual mu m-long faceted Fe3C nanowires. Anomalous magnetic features possibly due to strain effects of the crystal facets are reported. Magnetization measurements revealed unusual stepped magnetic hysteresis-loops at 300 K and at 2 K together with an anomalous decrease in the coercivity at low temperature. The observed unusual shape of the hysteresis is ascribed to the existence of an antiferromagnetic transition within or at the boundary of the ferromagnetic facets. The collapse in the coercivity value as the temperature decreases and the characteristic width-enhancement of the hysteresis with the field increasing appear to indicate the existence of layered antiferromagnetic phases, possibly in the strain-rich regions of the nanowire facets. Zero field cooled (ZFC) and field cooled (FC) magnetic curves evidenced presence of magnetic irreversibilities, an indicator of a possible spin-glass-like behavior induced by competing antiferromagnetic and ferromagnetic interactions. Characterization performed with low temperature XRD measurements, further revealed a slight variation in the average Fe3C unit cell parameters, suggesting the absence of additional unit-cell volume induced ferromagnetic transitions at low temperature.

Automated summary

In this study, carbon nanotubes filled with faceted Fe3C nanowires were observed, exhibiting anomalous magnetic properties possibly attributed to strain effects of the crystal facets. Magnetic measurements revealed stepped magnetic hysteresis-loops and decreased coercivity at low temperature, indicating the presence of antiferromagnetic transitions within or at the boundary of the ferromagnetic facets. The existence of layered antiferromagnetic phases and potential spin-glass-like behavior induced by competing antiferromagnetic and ferromagnetic interactions were suggested. Low temperature XRD measurements also hinted at a slight variation in the Fe3C unit cell parameters, implying the absence of additional unit-cell volume induced ferromagnetic transitions at low temperature.