14 results on '"*PHASE change memory"'
Search Results
2. Great Potential of Si-Te Ovonic Threshold Selector in Electrical Performance and Scalability.
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Wu, Renjie, Sun, Yuting, Zhang, Shuhao, Zhao, Zihao, and Song, Zhitang
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PHASE change memory , *PHASE change materials , *SCALABILITY , *STRAY currents , *THRESHOLD voltage - Abstract
The selector is an indispensable section of the phase change memory (PCM) chip, where it not only suppresses the crosstalk, but also provides high on-current to melt the incorporated phase change material. In fact, the ovonic threshold switching (OTS) selector is utilized in 3D stacking PCM chips by virtue of its high scalability and driving capability. In this paper, the influence of Si concentration on the electrical properties of Si-Te OTS materials is studied; the threshold voltage and leakage current remain basically unchanged with the decrease in electrode diameter. Meanwhile, the on-current density (Jon) increases significantly as the device is scaling down, and 25 MA/cm2 on-current density is achieved in the 60-nm SiTe device. In addition, we also determine the state of the Si-Te OTS layer and preliminarily obtain the approximate band structure, from which we infer that the conduction mechanism conforms to the Poole-Frenkel (PF) model. [ABSTRACT FROM AUTHOR]
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- 2023
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3. Nanoscale Phase Change Material Array by Sub-Resolution Assist Feature for Storage Class Memory Application.
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Zhang, Jiarui, Fang, Wencheng, Wang, Ruobing, Li, Chengxing, Zheng, Jia, Zou, Xixi, Song, Sannian, Song, Zhitang, and Zhou, Xilin
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PHASE change materials , *PHASE change memory , *PLASMA etching , *PHASE transitions , *OPTICAL interference , *FRUIT drying - Abstract
High density phase change memory array requires both minimized critical dimension (CD) and maximized process window for the phase change material layer. High in-wafer uniformity of the nanoscale patterning of chalcogenides material is challenging given the optical proximity effect (OPE) in the lithography process and the micro-loading effect in the etching process. In this study, we demonstrate an approach to fabricate high density phase change material arrays with half-pitch down to around 70 nm by the co-optimization of lithography and plasma etching process. The focused-energy matrix was performed to improve the pattern process window of phase change material on a 12-inch wafer. A variety of patternings from an isolated line to a dense pitch line were investigated using immersion lithography system. The collapse of the edge line is observed due to the OPE induced shrinkage in linewidth, which is deteriorative as the patterning density increases. The sub-resolution assist feature (SRAF) was placed to increase the width of the lines at both edges of each patterning by taking advantage of the optical interference between the main features and the assistant features. The survival of the line at the edges is confirmed with around a 70 nm half-pitch feature in various arrays. A uniform etching profile across the pitch line pattern of phase change material was demonstrated in which the micro-loading effect and the plasma etching damage were significantly suppressed by co-optimizing the etching parameters. The results pave the way to achieve high density device arrays with improved uniformity and reliability for mass storage applications. [ABSTRACT FROM AUTHOR]
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- 2023
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4. The Effect of Carbon Doping on the Crystal Structure and Electrical Properties of Sb 2 Te 3.
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Zhang, Jie, Rong, Ningning, Xu, Peng, Xiao, Yuchen, Lu, Aijiang, Song, Wenxiong, Song, Sannian, Song, Zhitang, Liang, Yongcheng, and Wu, Liangcai
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PHASE change memory , *DOPING agents (Chemistry) , *CRYSTAL structure , *FACE centered cubic structure , *MOLECULAR clusters , *GALLIUM antimonide - Abstract
As a new generation of non-volatile memory, phase change random access memory (PCRAM) has the potential to fill the hierarchical gap between DRAM and NAND FLASH in computer storage. Sb2Te3, one of the candidate materials for high-speed PCRAM, has high crystallization speed and poor thermal stability. In this work, we investigated the effect of carbon doping on Sb2Te3. It was found that the FCC phase of C-doped Sb2Te3 appeared at 200 °C and began to transform into the HEX phase at 25 °C, which is different from the previous reports where no FCC phase was observed in C-Sb2Te3. Based on the experimental observation and first-principles density functional theory calculation, it is found that the formation energy of FCC-Sb2Te3 structure decreases gradually with the increase in C doping concentration. Moreover, doped C atoms tend to form C molecular clusters in sp2 hybridization at the grain boundary of Sb2Te3, which is similar to the layered structure of graphite. And after doping C atoms, the thermal stability of Sb2Te3 is improved. We have fabricated the PCRAM device cell array of a C-Sb2Te3 alloy, which has an operating speed of 5 ns, a high thermal stability (10-year data retention temperature 138.1 °C), a low device power consumption (0.57 pJ), a continuously adjustable resistance value, and a very low resistance drift coefficient. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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5. Advantages of Ta-Doped Sb 3 Te 1 Materials for Phase Change Memory Applications.
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Shao, Mingyue, Qiao, Yang, Xue, Yuan, Song, Sannian, Song, Zhitang, and Li, Xiaodan
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PHASE change memory , *PHASE transitions , *GALLIUM antimonide , *THERMAL stability , *GRAIN size - Abstract
Phase change memory (PCM), a typical representative of new storage technologies, offers significant advantages in terms of capacity and endurance. However, among the research on phase change materials, thermal stability and switching speed performance have always been the direction where breakthroughs are needed. In this research, as a high-speed and good thermal stability material, Ta was proposed to be doped in Sb3Te1 alloy to improve the phase transition performance and electrical properties. The characterization shows that Ta-doped Sb3Te1 can crystallize at temperatures up to 232 °C and devices can operate at speeds of 6 ns and 8 × 104 operation cycles. The reduction of grain size and the density change rate (3.39%) show excellent performances, which are both smaller than that of Ge2Sb2Te5 (GST) and Sb3Te1. These properties conclusively demonstrate that Ta incorporation of Sb3Te1 alloy is a material with better thermal stability and faster crystallization rates for PCM applications. [ABSTRACT FROM AUTHOR]
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- 2023
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6. The Relationship between Electron Transport and Microstructure in Ge 2 Sb 2 Te 5 Alloy.
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Liu, Cheng, Zheng, Yonghui, Xin, Tianjiao, Zheng, Yunzhe, Wang, Rui, and Cheng, Yan
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ELECTRON transport , *PHASE transitions , *PHASE change materials , *PHASE change memory , *RANDOM access memory - Abstract
Phase-change random-access memory (PCRAM) holds great promise for next-generation information storage applications. As a mature phase change material, Ge2Sb2Te5 alloy (GST) relies on the distinct electrical properties of different states to achieve information storage, but there are relatively few studies on the relationship between electron transport and microstructure. In this work, we found that the first resistance dropping in GST film is related to the increase of carrier concentration, in which the atomic bonding environment changes substantially during the crystallization process. The second resistance dropping is related to the increase of carrier mobility. Besides, during the cubic to the hexagonal phase transition, the nanograins grow significantly from ~50 nm to ~300 nm, which reduces the carrier scattering effect. Our study lays the foundation for precisely controlling the storage states of GST-based PCRAM devices. [ABSTRACT FROM AUTHOR]
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- 2023
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7. Pt Modified Sb 2 Te 3 Alloy Ensuring High−Performance Phase Change Memory.
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Qiao, Yang, Zhao, Jin, Sun, Haodong, Song, Zhitang, Xue, Yuan, Li, Jiao, and Song, Sannian
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PHASE change memory , *PLATINUM , *RECORDS management , *THERMAL stability , *PHASE change materials - Abstract
Phase change memory (PCM), due to the advantages in capacity and endurance, has the opportunity to become the next generation of general−purpose memory. However, operation speed and data retention are still bottlenecks for PCM development. The most direct way to solve this problem is to find a material with high speed and good thermal stability. In this paper, platinum doping is proposed to improve performance. The 10-year data retention temperature of the doped material is up to 104 °C; the device achieves an operation speed of 6 ns and more than 3 × 105 operation cycles. An excellent performance was derived from the reduced grain size (10 nm) and the smaller density change rate (4.76%), which are less than those of Ge2Sb2Te5 (GST) and Sb2Te3. Hence, platinum doping is an effective approach to improve the performance of PCM and provide both good thermal stability and high operation speed. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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8. Structural Assessment of Interfaces in Projected Phase-Change Memory.
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Bragaglia, Valeria, Jonnalagadda, Vara Prasad, Sousa, Marilyne, Sarwat, Syed Ghazi, Kersting, Benedikt, and Sebastian, Abu
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PHASE change memory , *TRANSMISSION electron microscopy , *THIN films , *COMPUTER storage devices - Abstract
Non-volatile memories based on phase-change materials have gained ground for applications in analog in-memory computing. Nonetheless, non-idealities inherent to the material result in device resistance variations that impair the achievable numerical precision. Projected-type phase-change memory devices reduce these non-idealities. In a projected phase-change memory, the phase-change storage mechanism is decoupled from the information retrieval process by using projection of the phase-change material's phase configuration onto a projection liner. It has been suggested that the interface resistance between the phase-change material and the projection liner is an important parameter that dictates the efficacy of the projection. In this work, we establish a metrology framework to assess and understand the relevant structural properties of the interfaces in thin films contained in projected memory devices. Using X-ray reflectivity, X-ray diffraction and transmission electron microscopy, we investigate the quality of the interfaces and the layers' properties. Using demonstrator examples of Sb and Sb2Te3 phase-change materials, new deposition routes as well as stack designs are proposed to enhance the phase-change material to a projection-liner interface and the robustness of material stacks in the devices. [ABSTRACT FROM AUTHOR]
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- 2022
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9. Abridging CMOS Technology.
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Wong, Hei
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ELECTROSTATIC discharges , *NANOELECTROMECHANICAL systems , *THIN films , *NANOSTRUCTURED materials , *METAL oxide semiconductors , *PHASE change memory , *COMPLEMENTARY metal oxide semiconductors - Abstract
It is possible that the existing CMOS technology will remain the mainstream integration technology for decades to come; newly discovered materials, such as emerging 2D materials in various forms, together with the achievements in atomic-level fabrication technology, will be available as technological options for overcoming some of the constraints in CMOS devices and fabrication technology, and could enrich and enhance certain aspects of CMOS technology. Whether from a device physics, fabrication technology, or process economics point of view, the practice of downsizing silicon-based CMOS devices will soon end. CMOS device downsizing based on silicon technology will end very soon, but it will be used for mainstream devices and integration technology for decades. [Extracted from the article]
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- 2022
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10. Crystallization and Electrical Properties of Ge-Rich GeSbTe Alloys.
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Cecchi, Stefano, Lopez Garcia, Iñaki, Mio, Antonio M., Zallo, Eugenio, Abou El Kheir, Omar, Calarco, Raffaella, Bernasconi, Marco, Nicotra, Giuseppe, and Privitera, Stefania M. S.
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SCANNING transmission electron microscopy , *PHASE change memory , *GERMANIUM alloys , *ALLOYS , *CRYSTALLIZATION - Abstract
Enrichment of GeSbTe alloys with germanium has been proposed as a valid approach to increase the crystallization temperature and therefore to address high-temperature applications of non-volatile phase change memories, such as embedded or automotive applications. However, the tendency of Ge-rich GeSbTe alloys to decompose with the segregation of pure Ge still calls for investigations on the basic mechanisms leading to element diffusion and compositional variations. With the purpose of identifying some possible routes to limit the Ge segregation, in this study, we investigate Ge-rich Sb2Te3 and Ge-rich Ge2Sb2Te5 with low (<40 at %) or high (>40 at %) amounts of Ge. The formation of the crystalline phases has been followed as a function of annealing temperature by X-ray diffraction. The temperature dependence of electrical properties has been evaluated by in situ resistance measurements upon annealing up to 300 °C. The segregation and decomposition processes have been studied by scanning transmission electron microscopy (STEM) and discussed on the basis of density functional theory calculations. Among the studied compositions, Ge-rich Ge2Sb2Te5 is found to be less prone to decompose with Ge segregation. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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11. Phase Change Ge-Rich Ge–Sb–Te/Sb 2 Te 3 Core-Shell Nanowires by Metal Organic Chemical Vapor Deposition.
- Author
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Kumar, Arun, Cecchini, Raimondo, Wiemer, Claudia, Mussi, Valentina, De Simone, Sara, Calarco, Raffaella, Scuderi, Mario, Nicotra, Giuseppe, and Longo, Massimo
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METAL organic chemical vapor deposition , *NANOWIRES , *ELECTRON energy loss spectroscopy , *HIGH resolution electron microscopy , *PHASE change memory , *PHASE change materials - Abstract
Ge-rich Ge–Sb–Te compounds are attractive materials for future phase change memories due to their greater crystallization temperature as it provides a wide range of applications. Herein, we report the self-assembled Ge-rich Ge–Sb–Te/Sb2Te3 core-shell nanowires grown by metal-organic chemical vapor deposition. The core Ge-rich Ge–Sb–Te nanowires were self-assembled through the vapor–liquid–solid mechanism, catalyzed by Au nanoparticles on Si (100) and SiO2/Si substrates; conformal overgrowth of the Sb2Te3 shell was subsequently performed at room temperature to realize the core-shell heterostructures. Both Ge-rich Ge–Sb–Te core and Ge-rich Ge–Sb–Te/Sb2Te3 core-shell nanowires were extensively characterized by means of scanning electron microscopy, high resolution transmission electron microscopy, X-ray diffraction, Raman microspectroscopy, and electron energy loss spectroscopy to analyze the surface morphology, crystalline structure, vibrational properties, and elemental composition. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
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12. Robust Simulations of Nanoscale Phase Change Memory: Dynamics and Retention.
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Ding, Feilong, Dong, Deqi, Chen, Yihan, Lin, Xinnan, and Zhang, Lining
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PHASE change memory , *DISCONTINUOUS precipitation , *RATE of nucleation - Abstract
A robust simulation framework was developed for nanoscale phase change memory (PCM) cells. Starting from the reaction rate theory, the dynamic nucleation was simulated to capture the evolution of the cluster population. To accommodate the non-uniform critical sizes of nuclei due to the non-isothermal conditions during PCM cell programming, an improved crystallization model was proposed that goes beyond the classical nucleation and growth model. With the above, the incubation period in which the cluster distributions reached their equilibrium was captured beyond the capability of simulations with a steady-state nucleation rate. The implications of the developed simulation method are discussed regarding PCM fast SET programming and retention. This work provides the possibility for further improvement of PCM and integration with CMOS technology. [ABSTRACT FROM AUTHOR]
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- 2021
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13. Effects of Interface Induced Natural Strains on Magnetic Properties of FeRh.
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Hong, Jeongmin, Yang, Tiannan, N'Diaye, Alpha T., Bokor, Jeffrey, and You, Long
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PHASE change memory , *MAGNETIC properties , *MAGNETIC transitions , *SCANNING probe microscopy , *LANDAU theory , *ANTIFERROMAGNETIC materials - Abstract
FeRh is a unique alloy which shows temperature dependent phase transition magnetic properties. The lattice parameter (a) of this CsCl-type (B2) structure is 4.1712 Å. It undergoes a first order transition from antiferromagnetic (AFM) to ferromagnetic (FM) order at around 370K and hysteretic behavior while cooling and heating. This meta-magnetic transition of FeRh is accompanied by an isotropic expansion in the unit cell volume, which indicates strong coupling between magnetic and structural properties of FeRh. Consequently, the magnetic and transport properties, such as magnetoresistance (MR), are changed during the transition. Due to its unique thermo-magnetic behaviors, FeRh is very important for future spintronic devices. The structure could be applicable for MR devices such as memory, sensors, and many other applications. It is critical to understand how to systematically influence phase transition of FeRh from naturally applied strains. Here, we investigate magnetic properties of FeRh in different strain environments induced by the substrates with different lattice parameters. The study was performed using synchrotron radiation, temperature dependent magnetometry, and magnetic scanning probe microscopy in addition to Landau theory calculations. We found that the naturally induced strains could modulate the magnetic phase locally and globally. The presence of the segments from the nucleation of the ferromagnetic domains, with a very thin layer in the antiferromagnetic matrix and the domain growth, were observed gradually. Using the systematic phenomena, it could be used for immediate applications in the future generation of phase change random access memory (PC-RAM) devices. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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14. Overview of Phase-Change Electrical Probe Memory.
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Wang, Lei, Ren, Wang, Wen, Jing, and Xiong, Bangshu
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PHASE transitions , *PHASE change memory , *COMPUTER storage devices , *CHALCOGENIDES - Abstract
Phase-change electrical probe memory has recently attained considerable attention owing to its profound potential for next-generation mass and archival storage devices. To encourage more talented researchers to enter this field and thereby advance this technology, this paper first introduces approaches to induce the phase transformation of chalcogenide alloy by probe tip, considered as the root of phase-change electrical probe memory. Subsequently the design rule of an optimized architecture of phase-change electrical probe memory is proposed based on a previously developed electrothermal and phase kinetic model, followed by a summary of the state-of-the-art phase-change electrical probe memory and an outlook for its future prospects. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
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