Stochastic Memory Devices for Security and Computing

With the widespread use of mobile computing and internet of things, secured communication and chip authentication have become extremely important. Hardware-based security concepts generally provide the best performance in terms of a good standard of security, low power consumption, and large-area density. In these concepts, the stochastic properties of nanoscale devices, such as the physical and geometrical variations of the process, are harnessed for true random number generators (TRNGs) and physical unclonable functions (PUFs). Emerging memory devices, such as resistive-switching memory (RRAM), phase-change memory (PCM), and spin-transfer torque magnetic memory (STT-MRAM), rely on a unique combination of physical mechanisms for transport and switching, thus appear to be an ideal source of entropy for TRNGs and PUFs. An overview of stochastic phenomena in memory devices and their use for developing security and computing primitives is provided. First, a broad classification of methods to generate true random numbers via the stochastic properties of nanoscale devices is presented. Then, practical implementations of stochastic TRNGs, such as hardware security and stochastic computing, are shown. Finally, future challenges to stochastic memory development are discussed

Low Power Memory/Memristor Devices and Systems

This reprint focusses on achieving low-power computation using memristive devices. The topic was designed as a convenient reference point: it contains a mix of techniques starting from the fundamental manufacturing of memristive devices all the way to applications such as physically unclonable functions, and also covers perspectives on, e.g., in-memory computing, which is inextricably linked with emerging memory devices such as memristors. Finally, the reprint contains a few articles representing how other communities (from typical CMOS design to photonics) are fighting on their own fronts in the quest towards low-power computation, as a comparison with the memristor literature. We hope that readers will enjoy discovering the articles within

Fabrication, Characterization and Integration of Resistive Random Access Memories

The functionalities and performances of today's computing systems are increasingly dependent on the memory block. This phenomenon, also referred as the Von Neumann bottleneck, is the main motivation for the research on memory technologies. Despite CMOS technology has been improved in the last 50 years by continually increasing the device density, today's mainstream memories, such as SRAM, DRAM and Flash, are facing fundamental limitations to continue this trend. These memory technologies, based on charge storage mechanisms, are suffering from the easy loss of the stored state for devices scaled below 10 nm. This results in a degradation of the performance, reliability and noise margin. The main motivation for the development of emerging non volatile memories is the study of a different mechanism to store the digital state in order to overcome this challenge. Among these emerging technologies, one of the strongest candidate is Resistive Random Access Memory (ReRAM), which relies on the formation or rupture of a conductive filament inside a dielectric layer. This thesis focuses on the fabrication, characterization and integration of ReRAM devices. The main subject is the qualitative and quantitative description of the main factors that influence the resistive memory electrical behavior. Such factors can be related either to the memory fabrication or to the test environment. The first category includes variations in the fabrication process steps, in the device geometry or composition. We discuss the effect of each variation, and we use the obtained database to gather insights on the ReRAM working mechanism and the adopted methodology by using statistical methods. The second category describes how differences in the electrical stimuli sent to the device change the memory performances. We show how these factors can influence the memory resistance states, and we propose an empirical model to describe such changes. We also discuss how it is possible to control the resistance states by modulating the number of input pulses applied to the device. In the second part of this work, we present the integration of the fabricated devices in a CMOS technology environment. We discuss a Verilog-A model used to simulate the device characteristics, and we show two solutions to limit the sneak-path currents for ReRAM crossbars: a dedicated read circuit and the development of selector devices. We describe the selector fabrication, as well as the electrical characterization and the combination with our ReRAMs in a 1S1R configuration. Finally, we show two methods to integrate ReRAM devices in the BEoL of CMOS chips