Phase-change materials (PCMs) represent the leading candidates for universal data storage devices, which exploit the large difference in the physical properties of their transitional lattice structures. On a nanoscale, it is fundamental to determine their performance, which is ultimately controlled by the speed limit of transformation among the different structures involved. Here, we report observation with atomic-scale resolution of transient structures of nanofilms of crystalline germanium telluride, a prototypical PCM, using ultrafast electron crystallography. A nonthermal transformation from the initial rhombohedral phase to the cubic structure was found to occur in 12 ps. On a much longer time scale, hundreds of picoseconds, equilibrium heating of the nanofilm is reached, driving the system toward amorphization, provided that high excitation energy is invoked. These results elucidate the elementary steps defining the structural pathway in the transformation of crystalline-to-amorphous phase transitions and describe the essential atomic motions involved when driven by an ultrafast excitation. The establishment of the time scales of the different transient structures, as reported here, permits determination of the possible limit of performance, which is crucial for high-speed recording applications of PCMs.

Hu, J., Vanacore, G., Yang, Z., Miao, X., Zewail, A. (2015). Transient Structures and Possible Limits of Data Recording in Phase-Change Materials. ACS NANO, 9(7), 6728-6737 [10.1021/acsnano.5b01965].

Transient Structures and Possible Limits of Data Recording in Phase-Change Materials

Vanacore, G;
2015

Abstract

Phase-change materials (PCMs) represent the leading candidates for universal data storage devices, which exploit the large difference in the physical properties of their transitional lattice structures. On a nanoscale, it is fundamental to determine their performance, which is ultimately controlled by the speed limit of transformation among the different structures involved. Here, we report observation with atomic-scale resolution of transient structures of nanofilms of crystalline germanium telluride, a prototypical PCM, using ultrafast electron crystallography. A nonthermal transformation from the initial rhombohedral phase to the cubic structure was found to occur in 12 ps. On a much longer time scale, hundreds of picoseconds, equilibrium heating of the nanofilm is reached, driving the system toward amorphization, provided that high excitation energy is invoked. These results elucidate the elementary steps defining the structural pathway in the transformation of crystalline-to-amorphous phase transitions and describe the essential atomic motions involved when driven by an ultrafast excitation. The establishment of the time scales of the different transient structures, as reported here, permits determination of the possible limit of performance, which is crucial for high-speed recording applications of PCMs.
Articolo in rivista - Articolo scientifico
Ge-Sb-Te alloy; germanium telluride; phase transitions; phase-change materials; structural dynamics; ultrafast electron diffraction;
Ultrafast Electron Diffraction; phase-change materials; GeTe; atomic-scale dynamics
English
2015
9
7
6728
6737
none
Hu, J., Vanacore, G., Yang, Z., Miao, X., Zewail, A. (2015). Transient Structures and Possible Limits of Data Recording in Phase-Change Materials. ACS NANO, 9(7), 6728-6737 [10.1021/acsnano.5b01965].
File in questo prodotto:
Non ci sono file associati a questo prodotto.

I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.

Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/253488
Citazioni
  • Scopus 42
  • ???jsp.display-item.citation.isi??? 39
Social impact