AI Article Synopsis
- The study investigates the short-range order in liquid silicon (Si), germanium (Ge), and their binary alloys using x-ray diffraction and simulations, focusing on supercooled states.
- The experiments employed advanced techniques like aerodynamic levitation and CO2 laser heating to achieve deeper supercooling than previous studies.
- Findings reveal that the local atomic structure of these liquids resembles the-tin structure, showing consistent coordination numbers, but developing tetrahedral ordering suggests a transition from a high-density liquid phase to a lower-density phase akin to diamond structure.
Article Abstract
The short-range order in liquid Si, Ge and binary Si-Gealloys (= 0.25, 0.50, 0.75) was studied by x-ray diffraction and reverse Monte Carlo simulations. Experiments were performed in the normal and supercooled liquid states by using the containerless technique of aerodynamic levitation with COlaser heating, enabling deeper supercooling of liquid Si and Si-Ge alloys than previously reported. The local atomic structure of liquid Si and Ge resembles the-tin structure. The first coordination numbers of about 6 for all compositions are found to be independent of temperature indicating the supercooled liquids studied retain this high-density liquid (HDL) structure. However, there is evidence of developing local tetrahedral ordering, as manifested by a shoulder on the right side of the first peak in() which becomes more prominent with increasing supercooling. This result is potentially indicative of a continuous transition from the stable HDL-tin (high pressure) phase, towards a metastable low-density liquid phase, reminiscent of the diamond (ambient pressure) structure.
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| http://dx.doi.org/10.1088/1361-648X/abf593 | DOI Listing |
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