Structural and vibrational properties of Co nanoparticles formed by ion implantation
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Date
Authors
Sprouster, D. J.
Giulian, R.
Araujo, L. L.
Kluth, P.
Johannessen, B.
Cookson, D. J.
Foran, G. J.
Ridgway, M. C.
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American Institute of Physics (AIP)
Abstract
We report on the structural and vibrational properties of Co nanoparticles formed by ion
implantation and thermal annealing in amorphous silica. The evolution of the nanoparticle size,
phase, and structural parameters were determined as a function of the formation conditions using
transmission electron microscopy, small-angle x-ray scattering, and x-ray absorption spectroscopy.
The implantation fluence and annealing temperature governed the spherical nanoparticle size and
phase. To determine the latter, x-ray absorption near-edge structure analysis was used to quantify the
hexagonal close packed, face-centered cubic and oxide fractions. The structural properties were
characterized by extended x-ray absorption fine structure spectroscopy (EXAFS) and finite-size
effects were readily apparent. With a decrease in nanoparticle size, an increase in structural disorder
and a decrease in both coordination number and bondlength were observed as consistent with the
non-negligible surface-area-to-volume ratio characteristic of nanoparticles. The surface tension of
Co nanoparticles calculated using a liquid drop model was more than twice that of bulk material.
The size-dependent vibrational properties were probed with temperature-dependent EXAFS
measurements. Using a correlated anharmonic Einstein model and thermodynamic perturbation
theory, Einstein temperatures for both nanoparticles and bulk material were determined. Compared
to bulk Co, the mean vibrational frequency of the smallest nanoparticles was reduced as attributed
to a greater influence of loosely bonded, undercoordinated surface atoms relative to the effect of
capillary pressure generated by surface curvature.
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Keywords
structural and vibrational properties, Co nanoparticles, thermal annealing, amorphous silica, nanoparticle size, structural parameters, transmission electron microscopy, small-angle x-ray scattering, x-ray absorption spectroscopy., implantation fluence, annealing temperature, spherical nanoparticle size
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Journal of Applied Physics
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