Projected Mushroom Type Phase‐Change Memory

Sarwat, Syed Ghazi; Philip, Timothy M.; Chen, Ching-Tzu; Kersting, Benedikt; Bruce, Robert L.; Cheng, Cheng-Wei; Li, Ning; Saulnier, Nicole; BrightSky, M.; Sebastian, Abu

doi:10.1002/adfm.202106547

Cited by 26 publications

(18 citation statements)

References 36 publications

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“…Figure 4 shows XRR results of the C 34 (Sb 2 Te) 66 film, and the corresponding Bragg fitting is obtained according to the formula 51 (1) where α is the radian value of the incident angle, δ is related to the scatter, m is the order of reflection, Δm is a 1/2 or 0 (1/2 in our calculation), and λ is the wavelength. The following relationship gives the film thickness t (2) where k is the slope. The density change is calculated by the equation (3) Here, ρ mc and ρ ma represent the density of the film, and α cc 2 and α ca 2 denote critical angles of the XRR.…”

Section: Results and Analysesmentioning

confidence: 99%

“…Chalcogenide-based nanomaterials exhibit a reversible phase transition and form the basis of devices including phase-change memory (PCM), chalcogenide memristors, electro-optic mixed devices, optical storage devices, and neuromorphic devices. − The chalcogenide Ge 2 Sb 2 Te 5 (GST) has been intensely studied experimentally and theoretically. However, the unsatisfactory thermal stability and data retention, slow crystallization speed and operation speed (∼50 ns), large density change upon phase transition, resistance drift, etc.…”

Section: Introductionmentioning

confidence: 99%

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Graphite Carbon-Doped Sb₂Te Nanostructures for Phase-Change Memory Applications

Meng

et al. 2023

ACS Appl. Nano Mater.

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High thermal stability, fast operation speed, low thickness variation, and low resistance drift of phase-change nanomaterials are the essential characteristics in phase-change memory (PCM) applications. In this work, we put forward a graphite carbon-doped Sb2Te (C-Sb2Te) chalcogenide with semiconductor process compatibility. Our results prove that the proposed C-Sb2Te has excellent thermal stability and high operation speed. More importantly, the thickness change and resistance drift are only 0.89% and 0.0149, respectively. The C-Sb2Te-based memory device exhibits a high switching speed to the instrument test limit (5 ns) with a large resistance ratio, low operation voltage (2 V), and low power consumption (6.9 pJ). The proposed C-Sb2Te nanostructure material exceeds both conventional Ge2Sb2Te5 and transition-metal-doped Sb2Te materials in terms of its performance. Ab initio molecular dynamics simulations reveal that C–C and C–Sb bonds as well as C–C chains are formed in C-Sb2Te, and C doping constrains phase transition in a small region and refines grains of C-Sb2Te, thus resulting in the high performance. Our study suggests that C-Sb2Te is a potential candidate for high-speed, high-thermal-stability, and high-reliability PCM applications.

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Section: Results and Analysesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Graphite Carbon-Doped Sb₂Te Nanostructures for Phase-Change Memory Applications

Meng

et al. 2023

ACS Appl. Nano Mater.

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“…Benchmarking of reset current density ( J reset ) and resistance drift coefficient ( v ) for various PCM technologies. Simultaneously low J reset and low v are achieved in our SL-PCM (with 2/1.8 nm/nm Sb 2 Te 3 /GST and 32 internal interfaces), approaching the most desirable corner on this plot, compared to other PCM technologies from the literature. ,,− (The best corner is defined by the region where both J reset and v are simultaneously low.) SL-PCMs and control GST in this work are shown with red stars and red circle, respectively.…”

mentioning

confidence: 78%

“…This establishes the importance of SL material optimization and interface control (e.g., choice of SL material layers, their period thickness, suitable deposition conditions, and methods) for next-generation, low-power and high-density SL-PCM technology. The benchmarking plot in Figure also highlights the advantages of superlattice-based PCM technology compared to other existing PCM technologies ,− ,, in reducing PCM switching current and resistance drift simultaneously.…”

mentioning

confidence: 93%

Unveiling the Effect of Superlattice Interfaces and Intermixing on Phase Change Memory Performance

Khan

Perez

et al. 2022

Nano Lett.

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Superlattice (SL) phase change materials have shown promise to reduce the switching current and resistance drift of phase change memory (PCM). However, the effects of internal SL interfaces and intermixing on PCM performance remain unexplored, although these are essential to understand and ensure reliable memory operation. Here, using nanometer-thin layers of Ge 2 Sb 2 Te 5 and Sb 2 Te 3 in SL-PCM, we uncover that both switching current density (J reset ) and resistance drift coefficient (v) decrease as the SL period thickness is reduced (i.e., higher interface density); however, interface intermixing within the SL increases both. The signatures of distinct versus intermixed interfaces also show up in transmission electron microscopy, X-ray diffraction, and thermal conductivity measurements of our SL films. Combining the lessons learned, we simultaneously achieve low J reset ≈ 3−4 MA/ cm 2 and ultralow v ≈ 0.002 in mushroom-cell SL-PCM with ∼110 nm bottom contact diameter, thus advancing SL-PCM technology for high-density storage and neuromorphic applications.

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“…6 Phase-change memory (PCM) is an active area in nonvolatile memory devices. 7,8 It is based on rapid and reversible phase changes and is accompanied with electrical and optical switches. PCMs may be suitable for neuro-inspired computing systems because of their low energy consumption and multilevel states.…”

Section: Introductionmentioning

confidence: 99%