Structural and Magnetic Characteristics of MnAs Nanoclusters Embedded in Be-doped GaAs

TL;DR

This study investigates the synthesis, structure, and magnetic properties of MnAs nanoclusters embedded in Be-doped GaAs, revealing how Mn content influences cluster size, distribution, and magnetic behavior, including superparamagnetism and room-temperature magnetism.

Contribution

It provides a systematic analysis of how Mn content affects nanocluster formation and magnetic properties in MnAs/GaAs nanomaterials synthesized via in situ annealing.

Findings

Small clusters (~6 nm) exhibit superparamagnetism with low blocking temperature (~10 K).

Higher Mn content leads to larger MnAs clusters (~25 nm) with supermagnetic properties above room temperature.

Abstract

We describe a systematic study of the synthesis, microstructure and magnetization of hybrid ferromagnet-semiconductor nanomaterials comprised of MnAs nanoclusters embedded in a p-doped GaAs matrix. These samples are created during the in situ annealing of Be-doped (Ga,Mn)As heterostructures grown by molecular beam epitaxy. Transmission electron microscopy and magnetometry studies reveal two distinct classes of nanoclustered samples whose structural and magnetic properties depend on the Mn content of the initial (Ga,Mn)As layer. For Mn content in the range 5% - 7.5%, annealing creates a superparamagnetic material with a uniform distribution of small clusters (diameter around 6 nm) and with a low blocking temperature (T_B approximately 10 K). While transmission electron microscopy cannot definitively identify the composition and crystalline phase of these small clusters, our experimental data suggest that they may be comprised of either zinc-blende MnAs or Mn-rich regions of (Ga,Mn)As. At higher Mn content (> 8 %), we find that annealing results in an inhomogeneous distribution of both small clusters as well as much larger NiAs-phase MnAs clusters (diameter around 25 nm). These samples also exhibit supermagnetism, albeit with substantially larger magnetic moments and coercive fields, and blocking temperatures well above room temperature.