Self-assembly of magnetic nanoclusters in diamond-like carbon by diffusion processes enhanced by collision cascades

Mono-energetic cobalt implantation into hydrogenated diamond-like carbon at room temperature results in a bimodal distribution of implanted atoms without any thermal treatment. The ∼100 nm thin films were synthesised by mass selective ion beam deposition. The films were implanted with cobalt at an e...

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Bibliographic Details
Published in:Applied physics letters 2017-04, Vol.110 (14)
Main Authors: Gupta, P., Williams, G. V. M., Hübner, R., Vajandar, S., Osipowicz, T., Heinig, K-H., Becker, H-W., Markwitz, A.
Format: Article
Language:English
Subjects:
Applied physics
Backscattering
Cascades
Chemical synthesis
Cobalt
Diamond-like carbon films
Heat treatment
Ion current density
Ion currents
Ion implantation
Magnetic semiconductors
Nanoclusters
Nanoparticles
Normal distribution
Self-assembly
Spikes (lattice defects)
Thin films
Transmission electron microscopy
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Summary:Mono-energetic cobalt implantation into hydrogenated diamond-like carbon at room temperature results in a bimodal distribution of implanted atoms without any thermal treatment. The ∼100 nm thin films were synthesised by mass selective ion beam deposition. The films were implanted with cobalt at an energy of 30 keV and an ion current density of ∼5 μA cm−2. Simulations suggest the implantation profile to be single Gaussian with a projected range of ∼37 nm. High resolution Rutherford backscattering measurements reveal that a bimodal distribution evolves from a single near-Gaussian distribution as the fluence increases from 1.2 to 7 × 1016 cm−2. Cross-sectional transmission electron microscopy further reveals that the implanted atoms cluster into nanoparticles. At high implantation doses, the nanoparticles assemble primarily in two bands: one near the surface with nanoparticle diameters of up to 5 nm and the other beyond the projected range with ∼2 nm nanoparticles. The bimodal distribution along with the nanoparticle formation is explained with diffusion enhanced by energy deposited during collision cascades, relaxation of thermal spikes, and defects formed during ion implantation. This unique distribution of magnetic nanoparticles with the bimodal size and range is of significant interest to magnetic semiconductor and sensor applications.
ISSN:0003-6951
1077-3118
DOI:10.1063/1.4979523