Colloidal Phase-Change Materials Synthesis of Monodisperse GeTe Nanoparticles and Quantification of Their Size-Dependent Crystallization

Colloidal Phase-Change Materials : Synthesis of Monodisperse GeTe Nanoparticles and Quantification of Their Size-Dependent Crystallization

Phase-change memory materials refer to a class of materials that can exist in amorphous and crystalline phases with distinctly different electrical or optical properties, as well as exhibit outstanding crystallization kinetics and optimal phase transition temperatures. This paper focuses on the pote...

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Veröffentlicht in:Chemistry of materials : a publication of the American Chemical Society. - 1998. - 30(2018), 17 vom: 11. Sept., Seite 6134-6143
1. Verfasser: Yarema, Olesya (VerfasserIn)
Weitere Verfasser: Perevedentsev, Aleksandr, Ovuka, Vladimir, Baade, Paul, Volk, Sebastian, Wood, Vanessa, Yarema, Maksym
Format: Online-Aufsatz
Sprache:English
Veröffentlicht: 2018
Zugriff auf das übergeordnete Werk:Chemistry of materials : a publication of the American Chemical Society
Schlagworte:Journal Article
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520 |a Phase-change memory materials refer to a class of materials that can exist in amorphous and crystalline phases with distinctly different electrical or optical properties, as well as exhibit outstanding crystallization kinetics and optimal phase transition temperatures. This paper focuses on the potential of colloids as phase-change memory materials. We report a novel synthesis for amorphous GeTe nanoparticles based on an amide-promoted approach that enables accurate size control of GeTe nanoparticles between 4 and 9 nm, narrow size distributions down to 9-10%, and synthesis upscaling to reach multigram chemical yields per batch. We then quantify the crystallization phase transition for GeTe nanoparticles, employing high-temperature X-ray diffraction, differential scanning calorimetry, and transmission electron microscopy. We show that GeTe nanoparticles crystallize at higher temperatures than the bulk GeTe material and that crystallization temperature increases with decreasing size. We can explain this size-dependence using the entropy of crystallization model and classical nucleation theory. The size-dependences quantified here highlight possible benefits of nanoparticles for phase-change memory applications 
650 4 |a Journal Article 
700 1 |a Perevedentsev, Aleksandr  |e verfasserin  |4 aut 
700 1 |a Ovuka, Vladimir  |e verfasserin  |4 aut 
700 1 |a Baade, Paul  |e verfasserin  |4 aut 
700 1 |a Volk, Sebastian  |e verfasserin  |4 aut 
700 1 |a Wood, Vanessa  |e verfasserin  |4 aut 
700 1 |a Yarema, Maksym  |e verfasserin  |4 aut 
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