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Abstract

Thin films of $(Ge_{1–x}Sn_{x})_{8}Sb_{2}Te_{11}$ are prepared to study the impact of Sn‐substitution on properties relevant for application in phase‐change memory, a next‐generation electronic data storage technology. It is expected that substitution decreases the crystallization temperature, but it is not known how the maximum crystallization rate is affected. $Ge_{8}Sb_{2}Te_{11}$ is chosen from the $(GeTe) _{y}(Sb _{2}Te _{3}) _{1–y}$ system of phase‐change materials as a starting point due to its higher crystallization temperature as compared to the common material $Ge_{2}Sb_{2}Te_{5}$. In situ X‐ray diffraction at 5 K $min^{−1}$ heating rate is performed to determine the crystallization temperature and the resulting structure. To measure the maximum crystallization rate, femtosecond optical pulses that heat the material repetitively and monitor the resulting increase of optical reflectance are used. Glasses over the entire composition range are prepared using a melt‐quenching process. While at x = 0, 97, subsequent pulses are required for crystallization, one single pulse is enough to achieve the same effect at x = 0.5. The samples are further characterized by optical ellipsometry and calorimetry. The combined electrical and optical contrast and the ability to cycle between states with single femtosecond pulses renders $Ge_{4}Sn_{4}Sb_{2}Te_{11}$ promising for photonics applications.

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