Browsing by Author "Comrie, C M"
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- ItemOpen AccessEffect of high temperature deposition on CoSi 2 phase formation(2013) Comrie, C M; Ahmed, H; Smeets, D; Demeulemeester, J; Turner, S; Van Tendeloo, G; Detavernier, C; Vantomme, AAbstract: This paper discusses the nucleation behaviour of the CoSi to CoSi2 transformation from cobalt silicide thin films grown by deposition at elevated substrate temperatures ranging from 375 °C to 600 °C. A combination of channelling, real-time Rutherford backscattering spectrometry, real-time x-ray diffraction, and transmission electron microscopy was used to investigate the effect of the deposition temperature on the subsequent formation temperature of CoSi2, its growth behaviour, and the epitaxial quality of the CoSi2 thus formed. The temperature at which deposition took place was observed to exert a significant and systematic influence on both the formation temperature of CoSi2 and its growth mechanism. CoSi films grown at the lowest temperatures were found to increase the CoSi2 nucleation temperature above that of CoSi2 grown by conventional solid phase reaction, whereas the higher deposition temperatures reduced the nucleation temperature significantly. In addition, a systematic change in growth mechanism of the subsequent CoSi2 growth occurs as a function of deposition temperature. First, the CoSi2 growth rate from films grown at the lower reactive deposition temperatures is substantially lower than that grown at higher reactive deposition temperatures, even though the onset of growth occurs at a higher temperature, Second, for deposition temperatures below 450 °C, the growth appears columnar, indicating nucleation controlled growth. Elevated deposition temperatures, on the other hand, render the CoSi2 formation process layer-by-layer which indicates enhanced nucleation of the CoSi2 and diffusion controlled growth. Our results further indicate that this observed trend is most likely related to stress and changes in microstructure introduced during reactive deposition of the CoSi film. The deposition temperature therefore provides a handle to tune the CoSi2 growth mechanism.
- ItemOpen AccessIn situ study of the growth properties of Ni-rare earth silicides for interlayer and alloy systems on Si(100)(2012) Demeulemeester, J; Knaepen, W; Smeets, D; Schrauwen, A; Comrie, C M; Barradas, N P; Vieira, A; Detavernier, C; Temst, K; Vantomme, AWe report on the solid-phase reaction of thin Ni-rare earth films on a Si(100) substrate, for a variety of rare earth (RE) elements (Y, Gd, Dy, and Er). Both interlayer (Ni/RE/〈Si〉) and alloy (Ni-RE/〈Si〉) configurations were studied. The phase sequence during reaction was revealed using real-time x-ray diffraction whereas the elemental diffusion and growth kinetics were examined by real-time Rutherford backscattering spectrometry. All RE elements studied exert a similar influence on the solid phase reaction. Independent of the RE element or its initial distribution a ternary Ni 2Si2 RE phase forms, which ends up at the surface after NiSi growth. With respect to growth kinetics, the RE metal addition hampers the Ni diffusion process even for low concentrations of 2.5 at. %, resulting in the simultaneous growth of Ni-rich silicide and NiSi. Moreover, the formation of Ni 2Si2 RE during NiSi growth alters the Ni diffusion mechanism in the interlayer causing a sudden acceleration of the Ni silicide growth. Besides a significant effect on the silicide growth, we have found that adding 5 at. % Er (relative to Ni) lowers the NiSi Schottky barrier height on n-type Si(100) by approximately 0.1 eV for the interlayer and alloy configuration.
- ItemOpen AccessInteraction of germanium with platinum group metals in lateral diffusion couples(2004) Habanyama, Adrian; Comrie, C MExisting materials and technologies in the semiconductor industry are approaching their physical limits as device sizes decrease significantly below 100 nm. The challenges of achieving the required lateral abruptness of semiconductor junctions and low junction leakage as well as low contact resistance require a careful rebuilding of the fundamental physics and materials platform on which to base a reliable manufacturing capability. As feature size continues to decrease, interconnects will also pose increasingly difficult challenges in terms of physics and materials. The study of lateral diffusion couples is particularly well suited for dealing with the above concerns. This thesis looks at metal-germanium systems of the Platinum Group Metals (PG Ms). It is of particular relevance to study possible applications of PG Ms in South Africa, the country being one of the major producers of these metals in the world today. The diffusion lengths in standard thin-film couples range from a few angstroms to several thousand angstroms. In lateral diffusion couples, phase formation could extend to lengths of around 100 µm. Solid-state interactions in both thin-film and bulk diffusion couples can therefore be investigated using lateral diffusion couples. In particular the transition between the two types of interactions can be studied.
- ItemOpen AccessOn the growth kinetics of Ni(Pt) silicide thin films(2013) Demeulemeester, J; Smeets, D; Comrie, C M; Barradas, N P; Vieira, A; Van Bockstael, C; Detavernier, C; Temst, K; Vantomme, AWe report on the effect of Pt on the growth kinetics of δ-Ni2Si and Ni 1−xPtxSi thin films formed by solid phase reaction of a Ni(Pt) alloyed thin film on Si(100). The study was performed by real-time Rutherford backscattering spectrometry examining the silicide growth rates for initial Pt concentrations of 0, 1, 3, 7, and 10 at. % relative to the Ni content. Pt was found to exert a drastic effect on the growth kinetics of both phases. δ-Ni2Si growth is slowed down tremendously, which results in the simultaneous growth of this phase with Ni 1−xPtxSi. Activation energies extracted for the Ni 1−xPtxSi growth process exhibit an increase from Ea = 1.35 ± 0.06 eV for binary NiSi to Ea = 2.7 ± 0.2 eV for Ni 1−xPtxSi with an initial Pt concentration of 3 at. %. Further increasing the Pt content to 10 at. % merely increases the activation energy for Ni 1−xPtxSi growth to Ea = 3.1 ± 0.5 eV.
- ItemOpen AccessOn the nucleation of PdSi and NiSi 2 during the ternary Ni(Pd)/Si(100) reaction(2013) Schrauwen, A; Demeulemeester, J; Kumar, A; Vandervorst, W; Comrie, C M; Detavernier, C; Temst, K; Vantomme, ADuring the solid phase reaction of a Ni(Pd) alloy with Si(100), phase separation of binary Ni- and Pd-silicides occurs. The PdSi monosilicide nucleates at temperatures significantly below the widely accepted nucleation temperature of the binary system. The decrease in nucleation temperature originates from the presence of the isomorphous NiSi, lowering the interface energy for PdSi nucleation. Despite the mutual solubility of NiSi and PdSi, the two binaries coexist in a temperature window of 100 °C. Only above 700 °C a Ni 1– x Pd x Si solid solution is formed, which in turn postpones the NiSi2 formation to a higher temperature due to entropy of mixing. Our findings highlight the overall importance of the interface energy for nucleation in ternary systems.