A zero density change phase change memory material: GeTe-O structural characteristics upon crystallisation

Zhou, Xilin; Dong, Weiling; Zhang, Hao; Simpson, Robert E.

doi:10.1038/srep11150

Cited by 46 publications

(49 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Extensive works have been done to explore the effects of oxygen or nitrogen on the properties of phase change material Ge 2 Sb 2 Te 5 (GST) and GeTe. [19][20][21][22][23][24][25] Some general conclusions have been made including that oxygen/nitrogen will modify the local structure of amorphous GST/GeTe due to the strong Ge-O/Ge-N bonding. Most importantly, the doping effects are about the crystallization kinetics, for example, it is found that N can slow down the crystal growth of GST, [26][27][28] which will improve the data-retention property of the amorphous GST.…”

Section: Introductionmentioning

confidence: 99%

“…Most importantly, the doping effects are about the crystallization kinetics, for example, it is found that N can slow down the crystal growth of GST, [26][27][28] which will improve the data-retention property of the amorphous GST. While for GeTe, oxygen was reported to increase its crystallization temperature, 21 thus enabling the application of GeTe at higher temperature. More recently, further experimental study 20 showed that oxygen can also increase the resistivity of GeTe, resulting in a substantial reduction of switching voltage for the devices based on GeTe-O films.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Insight into the role of oxygen in the phase-change material GeTe

Zhu

Zhou

et al. 2017

J. Mater. Chem. C

View full text Add to dashboard Cite

Oxygen is widely used to tune the performance of chalcogenide phase-change materials in the usage of phase-Change random access memory (PCRAM) which is considered as the most promising next-generation non-volatile memory. However, the microscopic role of oxygen in the write-erase process, i.e., the reversible phase transition between crystalline and amorphous state of phase-change materials is not clear yet. Using oxygen doped GeTe as an example, this work unravels the role of oxygen at the atomic scale by means of ab initio total energy calculations and ab initio molecular dynamics simulations. Our main finding is that after the amorphization and the subsequent re-crystallization process simulated by ab initio molecular dynamics, oxygen will drag one Ge atom out of its lattice site and both atoms stay in the interstitial region near the Te vacancy that was originally occupied by the oxygen, forming a "dumbbell-like" defect (O-V Te -Ge), which is in sharp contrast to the results of ab initio total energy calculations at 0 K showing that the oxygen prefers to substitute Te in crystalline GeTe. This specific defect configuration is found to be responsible for the slower crystallization speed and hence the improved data retention of oxygen doped GeTe as reported in recent experimental work.Moreover, we find that the oxygen will increase the effective mass of the carrier and thus increases the resistivity of GeTe. Our results unravel the microscopic mechanism of the oxygen-doping optimization of phase-change material GeTe, and the present reported mechanism can be applied to other oxygen doped ternary chalcogenide phase-change materials.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Insight into the role of oxygen in the phase-change material GeTe

Zhu

Zhou

et al. 2017

J. Mater. Chem. C

View full text Add to dashboard Cite

show abstract

“…The difference between T tr and the critical temperature, T c , is a measure of how far the transition is from being thermodynamically continuous and, although this should include the saturation temperature from Equation A.5, it is usually adequate to ignore it in fitting data above room temperature. Figures A.1b and A.1c show fits of a function of the form of Equation A.12 to data for e 4 and e a derived from the lattice parameters of Levin et al [7], Chatterji et al [16] and Hudspeth et al [15]. T tr was fixed at the experimental values and the resulting fit parameters are listed in Table A.II.…”

Section: Acknowledgmentsmentioning

confidence: 99%

“…GeTe is a remarkable material in several topical contexts, including as an end-member phase for crystal-to-amorphous phase change memory [1][2][3][4], for nanowire memory devices [5], as a base for thermoelectric materials [6.7] and as a ferroelectric at room temperature which retains "a reversible, size dependent polar-nonpolar transition in nanocrystal ensembles" [8]. Close interest arises because of the particular combination of structure and electronic properties which can give fast switching and stable storage.…”

Section: Introductionmentioning

confidence: 99%

Strain coupling, microstructure dynamics, and acoustic mode softening in germanium telluride

et al. 2016

View full text Add to dashboard Cite

GeTe is a material of intense topical interest due to its potential in the context of phase-change and nanowire memory devices, as a base for thermoelectric materials and as a ferroelectric. The combination of a soft optic mode and a Peierls distortion contributes large strains at the cubic -rhombohedral phase transition near 625 K and the role of these has been investigated through their influence on elastic and anelastic properties by resonant ultrasound spectroscopy. The underlying physics is revealed by softening of the elastic constants by ~30-45%, due to strong coupling of shear and volume strains with the driving order parameter and consistent with an improper ferroelastic transition which is weakly first order. The magnitude of the softening is permissive of the transition mechanism involving a significant order/disorder component. A Debye loss peak in the vicinity of 180 K is attributed to freezing of the motion of ferroelastic twin walls and the activation energy of ~0.07 eV is attributed to control by switching of the configuration of long and short Ge-Te bonds in the first coordination sphere around Ge. Precursor softening as the transition is approached from above can be described with a Vogel-Fulcher expression with a similar activation energy, which is attributed to coupling of acoustic modes with an unseen central mode that arises from dynamical clusters with local ordering of the Peierls distortion. The strain relaxation and ferroelastic behaviour of GeTe depend on both displacive and order/disorder effects but the dynamics of switching will be determined by changes in the configuration of distorted GeTe 6 octahedra, with a rather small activation energy barrier.

show abstract

“…In the same work, it was also observed that the PCM crystallization depends not only on the magnitude but also on the duration of applied current pulse [7]. However, poor thermal stability in amorphous phase GST and void formation due to volume shrinkage upon crystallization limit the GST application range [8]. In comparison to GST, GeTe has several advantages including higher stability in amorphous phase, ultra-fast reversible phase transition (µs-to crystallize and ns-to amorphized), and higher OFF/ON resistivity ratio.…”

Section: Introductionmentioning

confidence: 68%

A Phase Change Material for Reconfigurable Circuit Applications

Tomer

Coutu

2018

Applied Sciences

View full text Add to dashboard Cite

Abstract:The large resistance contrast between amorphous and crystalline states of phase change materials (PCM) makes them a promising candidate for data-storage applications. Germanium telluride (GeTe), an early member of the PCM family, shows~6 orders of magnitude difference in resistivity upon phase transition. In this paper, two different heating methods, direct (Joule) and indirect thermal heating, were applied to induce a phase transition in vertical and horizontal GeTe resistors. In the electrical measurements, it was observed that thermal heating produces a two orders of magnitude larger difference in GeTe resistivity that the Joule heating, irrespective of the resistor's geometry and orientation. It was also found that the large inter-electrode distances in horizontal resistors make them impractical for low voltage applications. In addition, a correlation in between crystallization voltage and resistor's geometrical parameters (i.e., inter-electrode distance and cross-sectional area) was also established. Here, it was found that the threshold voltage increases with resistor length, while it remains unaffected with a change in cross-sectional area. This work provides design guidelines to make use of not only GeTe but also other phase change materials in reconfigurable circuit applications.

show abstract

A zero density change phase change memory material: GeTe-O structural characteristics upon crystallisation

Cited by 46 publications

References 43 publications

Insight into the role of oxygen in the phase-change material GeTe

Insight into the role of oxygen in the phase-change material GeTe

Strain coupling, microstructure dynamics, and acoustic mode softening in germanium telluride

A Phase Change Material for Reconfigurable Circuit Applications

Contact Info

Product

Resources

About