TY - JOUR
T1 - Atomistic Modeling of Charge-Trapping Defects in Amorphous Ge-Sb-Te Phase-Change Memory Materials
AU - Konstantinou, Konstantinos
AU - Elliott, Stephen R.
N1 - Funding Information:
The work has been performed under the Project HPC‐EUROPA3 (INFRAIA‐2016‐1‐730897), with the support of the EC Research Innovation Action under the H2020 Programme; in particular, K.K. gratefully acknowledges the computer resources and technical support provided by the Barcelona Supercomputing Center (BSC). K.K. acknowledges financial support from the Academy of Finland project No. 322832 “NANOIONICS”. The authors wish to acknowledge the CSC–IT Center for Science, Finland, for computational resources. The authors thank Dr T. H. Lee for providing the amorphous models of GeTe and GeTe. The authors thank Dr J. Mavračić for providing the amorphous model of SbTe. 4 2 3
Publisher Copyright:
© 2023 The Authors. physica status solidi (RRL) Rapid Research Letters published by Wiley-VCH GmbH.
PY - 2023
Y1 - 2023
N2 - Understanding the nature of charge-trapping defects in amorphous chalcogenide alloy-based phase-change memory materials is important for tailoring the development of multilevel memory devices with increased data storage density. Herein, hybrid density-functional theory simulations have been employed to investigate electron- and hole-trapping processes in melt-quenched glassy models of four different Ge-Sb-Te compositions, namely, GeTe, Sb2Te3, GeTe4, and Ge2Sb2Te5. The calculations demonstrate that extra electrons and holes are spontaneously trapped, creating charge-trapping centers in the bandgap of the amorphous materials. Over- and undercoordinated atoms, tetrahedral and “see-saw” octahedral-like geometries, fourfold rings, homopolar bonds, near-linear triatomic configurations, and chain-like motifs comprise the range of the defective atomic environments that have been identified in the structural patterns of the charge-trapping sites inside the glassy networks. The results illustrate that charge trapping corresponds to an intrinsic property of the glassy Ge-Sb-Te systems, show the impact of electron and hole localization on the atomic bonding of these materials, and they may have important implications related to the operation of phase-change electronic-memory devices.
AB - Understanding the nature of charge-trapping defects in amorphous chalcogenide alloy-based phase-change memory materials is important for tailoring the development of multilevel memory devices with increased data storage density. Herein, hybrid density-functional theory simulations have been employed to investigate electron- and hole-trapping processes in melt-quenched glassy models of four different Ge-Sb-Te compositions, namely, GeTe, Sb2Te3, GeTe4, and Ge2Sb2Te5. The calculations demonstrate that extra electrons and holes are spontaneously trapped, creating charge-trapping centers in the bandgap of the amorphous materials. Over- and undercoordinated atoms, tetrahedral and “see-saw” octahedral-like geometries, fourfold rings, homopolar bonds, near-linear triatomic configurations, and chain-like motifs comprise the range of the defective atomic environments that have been identified in the structural patterns of the charge-trapping sites inside the glassy networks. The results illustrate that charge trapping corresponds to an intrinsic property of the glassy Ge-Sb-Te systems, show the impact of electron and hole localization on the atomic bonding of these materials, and they may have important implications related to the operation of phase-change electronic-memory devices.
KW - amorphous chalcogenide materials
KW - defect electronic states
KW - electron trapping
KW - electronic structures
KW - hole trapping
KW - phase-change memory
U2 - 10.1002/pssr.202200496
DO - 10.1002/pssr.202200496
M3 - Article
AN - SCOPUS:85153283129
SN - 1862-6254
VL - 17
JO - Physica Status Solidi - Rapid Research Letters
JF - Physica Status Solidi - Rapid Research Letters
IS - 8
ER -