Showing total 2 results

1. Statistical Fluctuations in HfO<bold>x</bold> Resistive-Switching Memory: Part I - Set/Reset Variability.

Author

Ambrogio, Stefano, Balatti, Simone, Cubeta, Antonio, Calderoni, Alessandro, Ramaswamy, Nirmal, and Ielmini, Daniele

Subjects

*NONVOLATILE random-access memory, *ELECTRIC potential, *THIN insulating films, *MONTE Carlo method, *ELECTRIC resistance

Abstract

Resistive switching memory (RRAM) relies on the voltage-driven formation/disruption of a conductive filament (CF) across a thin insulating layer. Due to the 1-D structure of the CF and discrete nature of defects, the set and reset states of the memory device generally display statistical variability from cycle to cycle. For projecting cell downscaling and designing improved programming operations, the variability as a function of the operation parameters, such as the maximum current in the set process and maximum voltage in the reset process, need to be evaluated and understood. This paper addresses set/reset variability, presenting statistical data for HfOx-based RRAM and introducing a physics-based Monte Carlo model for switching statistics. The model can predict the distribution of the set state as a function of the compliance (maximum) current during set and distribution of the reset state as a function of the stop (maximum) voltage during reset. Numerical modeling results are finally presented to provide additional insight into discrete fluctuation events. [ABSTRACT FROM AUTHOR]

Published

2014

2. RRAM Crossbar Array With Cell Selection Device: A Device and Circuit Interaction Study.

Author

Deng, Yexin, Huang, Peng, Chen, Bing, Yang, Xiaolin, Gao, Bin, Wang, Juncheng, Zeng, Lang, Du, Gang, Kang, Jinfeng, and Liu, Xiaoyan

Subjects

*NONVOLATILE random-access memory, *CROSSBAR switches (Electronics), *NONLINEAR theories, *MICROPROCESSORS, *COMPUTER simulation, *ELECTRIC power consumption, *ELECTRIC potential

Abstract

The resistive random access memory (RRAM) crossbar array has been extensively studied as one of the most promising candidates for future high-density nonvolatile memory technology. However, some problems caused by circuit and device interaction, such as sneak leakage paths, result in limited array size and large power consumption, which degrade the array performance significantly. Thus, the analysis on circuit and device interaction issue is imperative. In this paper, a simulation method is developed to investigate the critical issues correlated with the interaction between devices and the circuit. The simulations show that a large off/on ratio of resistance states of RRAM is beneficial for large readout margin (i.e., array size). The existence of the selector connected in series with an RRAM device can eliminate the need for high Ron resistance, which is critical for the array consisted of only RRAM cells. The readout margin is more sensitive to the variation of Ron and is determined by the nonlinearity of the I–V characteristics of RRAM, whereas the nonlinear characteristics of the selector device are beneficial for a larger readout margin. An optimal design scheme for turn-on voltage and conductance of the selector is proposed based on the simulation. [ABSTRACT FROM PUBLISHER]

Published

2013