Abstract
Self-assembled Cu/W multilayer thin films are fabricated and used as the top electrodes (TEs) in conductive-bridge random access memory (CBRAM) devices. The modulation period (λ) of the Cu/W multilayer structure can be well controlled by changing the substrate rotation speed during magnetron sputtering. For the λ value of 3.2 nm, the Al2O3 based CBRAM devices exhibits significantly improved resistive switching (RS) performances with effectively narrowed switching parameters and substantially increased OFF/ON ratio up to 104 at 0.10 V. Good reliability after 600 cycles is demonstrated and the retention time of 10 years at 85 °C is estimated through Arrhenius plot. In essential, the growth of conductive filaments (CFs) in Al2O3 layers is well controlled owing to the W-rich layer as the diffusion barrier. As a result, both the number and the size of CFs in Al2O3 layer are reduced if the λ value is increased. Especially, volatile RS behavior is evidenced due to the extremely slow diffusion of Cu ions across the TE/Al2O3 interface and thus the formation of tiny CFs if the λ value is up to 7.0 nm. A physical model is proposed to describe the controllable formation of CFs by using Cu/W multilayer TEs.
Published Version
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