Litcius/Paper detail

Understanding of Selector‐Less 1S1R Type Cu‐Based CBRAM Devices by Controlling Sub‐Quantum Filament

Writam Banerjee, Hyunsang Hwang

2020Advanced Electronic Materials36 citationsDOI

Abstract

Abstract This study demonstrates a systematic approach to design a sub‐quantum selector‐less conductive bridge random access memory (CBRAM) which can work as one‐selector‐one‐resistor device in Cu/Ti/HfO 2 /TiO 2 /TiN material stack, can work nicely from sub‐µA to sub‐nA range. Optimized high thermal forming scheme is investigated to control the anatomy of filament formation at sub‐nA current level. The thickness of HfO 2 layer plays a crucial role in determining such behavior. Hence, in this study the precise stack engineering is proposed and the selector‐less device design which can show highly stable one‐selector‐one‐resistor type performance at sub‐quantum level is identified. The TiO 2 ‐based selector device is verified experimentally and theoretically. The presence of 1 eV deep level traps by CuO defect sites in HfO 2 matrix with calculated nearest neighbor of 0.7 nm along with the presence of TiO 2 selector layer, is the origin of highly nonlinear behavior. The devices show ultra‐low leakage current of 300 fA (system limitation) and operated with ultra‐low power of 5 pW, very high resistance ratio of 3 × 10 3 , with high nonlinearity of 3 × 10 3 . This work establishes the possibility to design ultra‐low power nonvolatile sub‐quantum CBRAM device which can fulfill the needs of internet of things applications after optimization.

Topics & Concepts

Materials scienceResistorOptoelectronicsStack (abstract data type)TinProtein filamentElectrical conductorResistive random-access memoryQuantum dotNanotechnologyElectrical engineeringComputer scienceComposite materialVoltageMetallurgyEngineeringProgramming languageAdvanced Memory and Neural ComputingSemiconductor materials and devicesFerroelectric and Negative Capacitance Devices