Magnetic coupling of iron-based ferromagnetic nanoclusters encapsulated inside double-wall carbon nanotubes

IF 3.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Carbon Trends Pub Date : 2025-03-10 DOI:10.1016/j.cartre.2025.100483

Wilson Nieto , Johnny Chimborazo , Hidetsugu Shiozawa , Thomas Pichler , Paola Ayala , Dario Niebieskikwiat

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Abstract

Understanding the magnetic properties of hybrids of carbon nanotubes is an intriguing matter that offers a vastly unexplored playground for fundamental research and promising applications. The magnetic properties of bundles of double-wall carbon nanotubes encapsulating cementite ferromagnetic nanoclusters (of

\sim

3–4 nm in length) are here studied. VSM magnetometry shows clear evidence of interparticle magnetic interactions and a large interface exchange coupling of the nanoclusters with the carbon matrix, characterized by a surface anisotropy field

H_{K} \sim 67

kOe. Using a well-known measurement protocol, a magnetic activation volume for magnetization reversal was estimated as

\sim 420 {nm}^{3}

. This large volume involves around 270 cementite nanoparticles mutually coupled through the conduction electrons of the nanotubes, which provide the ground for a large magnetic correlation length, thus favoring their possible application in spintronic devices.

Abstract Image