超薄氧化铝层的电场调制效应

研究了基于高k介质材料的阻变存储器的写入/擦除 (SET/RESET) 特性和物理机制.研究发现基于NbAlO材料的阻变存储器SET/RESET电压具有较大波动性, 通过结构优化, 在Al2O3/NbAlO/Al2O3纳米薄片堆垛结构器件中获得高度稳定性的可重复的阻变特性.基于电场调制效应, 提出了一种统一的电阻开关模型去模拟阻变存储器的SET/RESET行为, 并探讨了单层阻变薄膜的阻变存储器中由导电单元形成和湮灭的巨大随机性引起的阻变特性分布.当在NbAlO基阻变存储器中嵌入超薄Al2O3膜后, 阻变存储器的SET/RESET电压稳定性将显著提升, 其原因在于采用堆垛结构的阻变器件中各介质层中的电场重新分布并精确可控, 因此导电细丝的导通/断裂通过电场调制作用稳定均匀地在发生在具有高电场的薄缓冲层介质层中.     

基于I-V特性的阻变存储器的阻变机制研究

随着器件尺寸的缩小,阻变存储器(RRAM)具有取代现有主流Flash存储器成为下一代新型存储器的潜力。但对RRAM器件电阻转变机制的研究在认识上依然存在很大的分歧,直接制约了RRAM的研发与应用。通过介绍阻变存储器的基本工作原理、不同的阻变机制以及基于阻变存储器所表现出的不同I-V特性,研究了器件的阻变特性;详细分析了阻变存储器的五种阻变物理机制,即导电细丝(filament)、空间电荷限制电流效应(SCLC)、缺陷能级的电荷俘获和释放、肖特基发射效应(Schottky emission)以及普尔-法兰克效应(Pool-Frenkel);同时,对RRAM器件的研究发展趋势以及面临的挑战进行了展望。     

铅基卤素钙钛矿阻变式存储器研究进展

随着数字通信在大数据以及物联网等领域的应用,推动了下一代存储设备的发展.阻变式存储器因其功耗低、尺寸可调、操作速度快等优点被认为是最有前景的信息存储器件之一.近年来,兼具成本低、带隙可调、载流子扩散长度长、离子迁移速率快、载流子迁移率高等优点的铅基卤素钙钛矿,在阻变式存储器领域引起了广泛关注.主要对铅基卤素钙钛矿阻变式...     

一种基于阻变单元特性的阻变存储器修复方案

针对新型阻变存储器(RRAM)工艺良率不高的问题,提出了一种新型的修复解决方案,该方案基于阻变单元的特殊性能,即初始状态为高阻,经过单元初始化操作过程后转变为低阻。利用这样特性的阻变单元作为错误检测位、冗余单元作为修复位,提出了三种不同的组织结构来实现修复操作。三种结构由于主存储器、检验位存储器及冗余存储器的组织方式不同,达到了不同的冗余存储器利用率。最后,通过数学分析可以证明,该方案在利用了较少冗余存储器的条件下,可以将阻变存储器的错误率普遍降低10～30倍,实现了较好的修复效果。     

一种NAND型三维多层1TXR阻变存储器设计

随着存储器市场逐渐受消费电子的驱动,对高密度低成本的存储需求正在不断增加.阻变存储器正在成为新型非挥发存储器的研究热点.提出一种适用于未来高密度应用的与非(NAND)型共享选通管的三维多层1TXR阻变存储器概念.在0.13 μm工艺下,以一个使用8层金属堆叠的1T64R结构为例,其存储密度比传统的单层1T1R结构高500%.提出了相关的读写操作方法来防止由漏电流造成的误写和误读并且降低功耗.     

阻变存储器及其集成技术研究进展

在各种新型非挥发性存储器中,阻变存储器(RRAM)具有成为下一代存储器的潜力.介绍了RRAM器件的基本结构,分类总结了常用的材料以及制备工艺,对RRAM阵列的集成方案进行了比较,并讨论了目前存在的问题;最后,对RRAM的研究趋势进行了展望.     

新型阻变存储器内的电压解决方案

相对于现在流行的FLASH型存储器,新型阻变存储器(resistive-RAM,RRAM)有很多优势,比如较高的存储密度和较快的读写速度。而针对RRAM的读写操作特性,提出了一种适用于新型阻变存储器的提供操作电压的电路。该方案解决了新型存储器需要外部提供高于电源电压的操作电压的问题,使得阻变存储器能应用于嵌入式设备。同时,对工艺波动和温度波动进行补偿,从而降低了阻变存储器的读写操作在较差的工艺和温度环境下的失败概率,具有很强的实际应用意义。该设计采用0.13μm标准CMOS 6层金属工艺在中芯国际(SMIC)流片实现,测试结果表明,采用此电路的RRAM能正确地进行数据编程和擦除等操作,测试结果达到设计要求。     

基于氧化钨的8 Mb高密度阻变存储器设计

设计了一款基于氧化钨的8Mb高密度阻变存储器,采用单晶体管开关、单电阻(1T1R)的存储器单元结构,设计了完整的存储单元、行列译码器、写驱动和灵敏放大器等关键模块。存储器芯片采用HHNEC 0.13μm 1P8M CMOS工艺流片。仿真结果表明,在8F2的高密度存储单元面积下,该存储器可实现准确的数据写入和读出功能。     

CuO纳米线阻变存储器的组装及电阻开关特性

用热氧化法在空气中加热铜片制备了CuO纳米线(CuO NWs),通过FESEM对纳米线表面进行了观察,并用液体转移法组装成功了一种简单的阻变存储器件。通过I-V测试系统观察到了Cu/CuO NWs/Cu器件表现出了明显的双极型和单极型。最后通过对比高阻态(HRS)和低阻态(LRS)的表面形貌,解释了Cu/CuO NWs/Cu器件的阻变机制。     

RRAM的氧空位与金属细丝机制SPM的比较

应用扫描探针显微镜(SPM)技术实现了氧化物阻变薄膜局部区域高低阻态的互相转变。通过电激励、编程和擦除等操作,控制细丝的产生和断裂,实现了阻变薄膜局域的重复编程/擦除操作。用该方法分别研究了氧空位机制与金属导电细丝机制的氧化物薄膜的阻变特性,对两种机制做了对比研究。结果表明:在阻变存储器(RRAM)中氧空位机制在导电细丝和数据密度方面要高于金属细丝机制。同时,金属细丝机制阻变薄膜部分区域因编程/擦除操作发生了永久性形貌变化,可能对阻变器件的电极产生永久性破坏,这说明氧空位机制阻变薄膜在未来的高密度存储上具有较好的应用前景。     

Resistive random access memory and its applications in storage and nonvolatile logic

The resistive random access memory (RRAM) device has been widely studied due to its excellent memory characteristics and great application potential in different fields. In this paper, resistive switching materials, switching mechanism, and memory characteristics of RRAM are discussed. Recent research progress of RRAM in high-density storage and nonvolatile logic application are addressed. Technological trends are also discussed.     

阻变存储阵列的自动化测试系统

阻变存储器(RRAM)是一种新型的不挥发存储技术,研究阻变存储器阵列规模的存储性能以及可靠性问题是推进RRAM实用化的关键.目前通用的基于微控探针台的半导体参数分析的常规测量系统无法完成对阵列的自动化测试.利用半导体参数分析仪(4200-SCS)、开关矩阵以及相关外围电路搭建了一套针对阻变存储阵列的自动测试系统,实现了1MbitRRAM芯片的初始阻态分布的读取、初始化测试、存储单元的自动化编程/擦除操作.测试结果表明,该测试系统可以实现阻变存储阵列的自动化测试,为进一步工艺参数和编程算法的优化设计奠定基础.     

A journey towards reliability improvement of TiO2 based Resistive Random Access Memory: A review

A Resistive Random Access Memory (RRAM), where the memory performance principally originated from ‘resistive’ change rather than ‘capacitive’ one (the case with conventional CMOS memory devices), has attracted researchers across the globe, owing to its unique features and advantages meeting the demands of future generation high-speed, ultra low power, nano dimensional memory devices. A large family of semiconducting oxides have been investigated as insulator for Resistive Random Access Memory (RRAM), amongst which TiO₂ is one of the potential candidate, principally owing to some of its remarkable advantages e.g. wide band gap, high temperature stability and high dielectric constant with flexibility to offer both unipolar and bipolar switching, which are essential for RRAM device applications. In this review article, we tried to represent the long voyage of TiO₂ based RRAM, towards the improvement of the reliability aspects of the device performance in a comprehensive manner. Starting with the key factors like oxygen vacancies, Ti interstitials and electroforming, which are responsible for resistive switching phenomenon, various material preparation techniques for RRAM development have been discussed with emphasis on relative merits and bottlenecks of the process. The factors like electrode material and geometry, device structuring, doping, compliance current, annealing effect etc., which play the pivotal role in determining the switching performance of the device, have been reviewed critically. Finally, the article concludes with the comparison of different TiO₂ based RRAM devices followed by the prediction of possible future research trends.     

缺陷相互作用对HfO2基阻变存储器件均匀性的影响：第一性原理研究

The physical mechanism of doping effects on switching uniformity and operation voltage in Al-doped HfO₂ resistive random access memory（RRAM） devices is proposed from another perspective:defects interactions, based on first principle calculations.In doped HfO₂,dopant is proved to have a localized effect on the formation of defects and the interactions between them.In addition,both effects cause oxygen vacancies（V_O） to have a tendency to form clusters and these clusters are easy to form around the dopant.It is proved that this process can improve the performance of material through projected density of states（PDOS） analysis.For V_O filament-type RRAM devices, these clusters are concluded to be helpful for the controllability of the switching process in which oxygen vacancy filaments form and break.Therefore,improved uniformity and operation voltage of Al-doped HfjO₂ RRAM devices is achieved.     

Low-Energy Oxygen Plasma Injection of 2D Bi2Se3 Realizes Highly Controllable Resistive Random Access Memory

Resistive random access memory (RRAM) based on ultrathin 2D materials is considered to be a very feasible solution for future data storage and neuromorphic computing technologies. However, controllability and stability are the problems that need to be solved for practical applications. Here, by introducing a damage-less ion implantation technology using ultralow-energy plasma, the transport mechanisms of space charge limited current and Schottky emission are successfully realized and controlled in RRAM based on 2D Bi₂Se₃ nanosheets. The memristors exhibit stable resistive switching behavior with a high resistive switching ratio (>10⁴), excellent cycling endurances (300 cycles), and great retention performance (>10⁴ s). The reliability and controllability of Bi₂Se₃ memory endowed by oxygen plasma injection demonstrate the great potential of this ultralow-energy ion implantation technology in the application of 2D RRAM.     

A Parallel Circuit Model for Multi‐State Resistive‐Switching Random Access Memory

Large, rapidly growing literature is available on bipolar resistive‐switching random access memories (RRAM) made of myriad of simple and advanced materials. Many of them exhibit similar resistance switching behavior but, until now, no unifying model can allow quantification of their voltage and time responses. Using a simple parallel circuit model, these responses of a newly discovered RRAM made of a thin‐film random material are successfully analyzed. The analysis clearly reveals a large population of intermediate states with remarkably similar switching characteristics. Such modeling framework based on simple circuit constructs also appears applicable to several RRAM made of other materials. This simple approach to analyze data write/rewrite and memory retention in RRAM may aid their further understanding and development.     

Control of Switching Modes and Conductance Quantization in Oxygen Engineered HfOx based Memristive Devices

Hafnium oxide (HfO_x)‐based memristive devices have tremendous potential as nonvolatile resistive random access memory (RRAM) and in neuromorphic electronics. Despite its seemingly simple two‐terminal structure, a myriad of RRAM devices reported in the rapidly growing literature exhibit rather complex resistive switching behaviors. Using Pt/HfO_x/TiN‐based metal–insulator–metal structures as model systems, it is shown that a well‐controlled oxygen stoichiometry governs the filament formation and the occurrence of multiple switching modes. The oxygen vacancy concentration is found to be the key factor in manipulating the balance between electric field and Joule heating during formation, rupture (reset), and reformation (set) of the conductive filaments in the dielectric. In addition, the engineering of oxygen vacancies stabilizes atomic size filament constrictions exhibiting integer and half‐integer conductance quantization at room temperature during set and reset. Identifying the materials conditions of different switching modes and conductance quantization contributes to a unified switching model correlating structural and functional properties of RRAM materials. The possibility to engineer the oxygen stoichiometry in HfO_x will allow creating quantum point contacts with multiple conductance quanta as a first step toward multilevel memristive quantum devices.     

铪/二氧化铪基双极阻变存储器特性研究

本文制备了纳米级Hf/HfO2阻变存储器（RRAM）。RRAM顶层电极和底部电极交叉，从而形成了金属-氧化物-金属结构。系统地研究了RRAM的电学特性，包括forming过程，SET过程和RESET过程。讨论了SET电压和RESET电压的相关性，以及高阻态和低阻态的相关性。RRAM的电学特性与SET过程中的限制电路强相关。可以基于量子点接触模型，阐述纳米级Hf/HfO2阻变存储器的导通机制。