International Topical Meeting on Nuclear Research Applications and Utilization of Accelerators
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AP/P2-05
High Ion Irradiation Tolerance of Multilayered AlN/TiN Nanocomposites M. Milosavljević;1, D. Peruško1, V. Milinović1, B. Timotijević1, A. Zalar2, J. Kovač2, and C. Jeynes3 1VINČA Institute of Nuclear Sciences, Belgrade, Serbia Corresponding Author: momirm@vinca.rs High strength multilayered metal or composite nanostructures are interesting as radiation protective
materials, because of a large number of interfaces that act as obstacles to slip and sinks for
radiation induced defects. In the investigations reported to date, mainly multilayers of immiscible
metals were studied, such as Cu/Nb, W/Ni, Cu/W or Mo/Cu. This study reports on the stability
of nanocrystalline AlN/TiN multilayers upon argon ion irradiation. The AlN/TiN system
was chosen because it exhibits high strength and temperature stability, and the constituents are
immiscible. Reactive sputtering was used to deposit (AlN/TiN)x5 films on (100) Si, to a total
thickness of ~270 nm. Argon ions were implanted at 200 keV, the projected ion range being
around mid-depth of the deposited structures. The applied fluences were high enough to induce
a marked intermixing in normally soluble or chemically reactive materials. Structural characterizations
of the samples were performed by Rutherford backscattering spectrometry (RBS), X-ray
photoelectron spectroscopy (XPS) and transmission electron microscopy (TEM). It was found that
the investigated AlN/TiN multilayers exhibit a remarkable ion irradiation stability. Ion irradiation
induced a slight increase of the mean grain size in individual layers, from ~10 nm to ~20 nm,
and small local density changes around the projected ion range. Apart from this, no distinct
intermixing of the layers was observed. Also, the interfaces remained sharp after irradiation to
all the applied fluences, which is crucial for structural stability of multilayered structures. The
results were compared to other systems and analyzed in terms of the existing ion beam mixing
models. The net mixing rate found was below the predictions of the ballistic model. In fact, in
immiscible systems thermal spikes and chemical driving forces invoke dynamic demixing, when
the knocked on particles are driven back across the interface. In conclusion, the results obtained
in this study suggest that immiscible metal-nitride multilayers should attract further attention as
radiation tolerant materials. |
