Phase Separation in Ge-Rich GeSbTe at Different Length Scales: Melt-Quenched Bulk versus Annealed Thin Films

Daniel Tadesse Yimam, A. J.T. Van Der Ree, Omar Abou El Kheir, Jamo Momand, Majid Ahmadi, George Palasantzas, Marco Bernasconi, Bart J. Kooi

Research output: Contribution to journalArticlepeer-review

5 Scopus citations

Abstract

Integration of the prototypical GeSbTe (GST) ternary alloys, especially on the GeTe-Sb2 Te3 tie-line, into non-volatile memory and nanophotonic devices is a relatively mature field of study. Nevertheless, the search for the next best active material with outstanding properties is still ongoing. This search is relatively crucial for embedded memory applications where the crystallization temperature of the active material has to be higher to surpass the soldering threshold. Increasing the Ge content in the GST alloys seems promising due to the associated higher crystallization temperatures. However, homogeneous Ge-rich GST in the as-deposited condition is thermodynamically unstable, and phase separation upon annealing is unavoidable. This phase separation reduces endurance and is detrimental in fully integrating the alloys into active memory devices. This work investigated the phase separation of Ge-rich GST alloys, specifically Ge5 Sb2 Te3 or GST523, into multiple (meta)stable phases at different length scales in melt-quenched bulk and annealed thin film. Electron microscopy-based techniques were used in our work for chemical mapping and elemental composition analysis to show the formation of multiple phases. Our results show the formation of alloys such as GST213 and GST324 in all length scales. Furthermore, the alloy compositions and the observed phase separation pathways agree to a large extent with theoretical results from density functional theory calculations.

Original languageEnglish
Article number1717
JournalNanomaterials
Volume12
Issue number10
DOIs
StatePublished - May 1 2022
Externally publishedYes

Funding

Funding: This work has received funding from the European Union Horizon 2020 research and innovation program under Grant Agreement No. 824957 (BeforeHand: Boosting Performance of Phase Change Devices by Hetero-and Nanostructure Material Design).

FundersFunder number
Horizon 2020 Framework Programme
Horizon 2020824957

    Keywords

    • EDX elemental chemical mapping
    • GGST
    • Ge-rich GST
    • density functional theory
    • embedded memory
    • phase change materials
    • phase separation
    • pulsed laser deposition

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