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1. Resistive Switching Characteristics of Fullerene (C60) in Polymannose Thin Film

   https://doi.org/10.1002/pssr.202200242  

   Cheong, Kuan Yew; Tayeb, Ilias Ait; Zhao, Feng (September 2022, physica status solidi (RRL) – Rapid Research Letters)

   The effects of C60 incorporated in polymannose‐based resistive switching memory have been systematically investigated for the first time in bioorganic‐based resistive switching memory. C60 with different concentrations (0–7 wt%) is dispersed in polymannose precursor, drop‐casted on ITO/PET substrate, and dried to form a thin film. Electrochemically inert Au–Pd is used as top electrode. The devices with embedded C60 show better endurance and stability. Read memory window decreases and ON/OFF ratio increases as the concentration of C60 increases. Stable retention time up to 10 years is achieved for all of the devices except the one with 7 wt% C60. Based on zeta potential measurement, polymannose is more negatively charged than C60. Hence, C60 functions as an effective interlock that bridges between long molecular chains of polymannose and enhances the resistive switching properties of the polymannose thin film. 

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2. Sulfurization Engineering of One‐Step Low‐Temperature MoS ₂ and WS ₂ Thin Films for Memristor Device Applications

   https://doi.org/10.1002/aelm.202100515  

   Gu, Yuqian; Serna, Martha_I; Mohan, Sivasakthya; Londoño‐Calderon, Alejandra; Ahmed, Taimur; Huang, Yifu; Lee, Jack; Walia, Sumeet; Pettes, Michael_T; Liechti, Kenneth_M; et al (October 2021, Advanced Electronic Materials)

   Abstract 2D materials have been of considerable interest as new materials for device applications. Non‐volatile resistive switching applications of MoS₂and WS₂have been previously demonstrated; however, these applications are dramatically limited by high temperatures and extended times needed for the large‐area synthesis of 2D materials on crystalline substrates. The experimental results demonstrate a one‐step sulfurization method to synthesize MoS₂and WS₂at 550 °C in 15 min on sapphire wafers. Furthermore, a large area transfer of the synthesized thin films to SiO₂/Si substrates is achieved. Following this, MoS₂and WS₂memristors are fabricated that exhibit stable non‐volatile switching and a satisfactory large on/off current ratio (10³–10⁵) with good uniformity. Tuning the sulfurization parameters (temperature and metal precursor thickness) is found to be a straightforward and effective strategy to improve the performance of the memristors. The demonstration of large‐scale MoS₂and WS₂memristors with a one‐step low‐temperature sulfurization method with simple strategy to tuning can lead to potential applications such as flexible memory and neuromorphic computing. 

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3. Enhanced non-volatile resistive switching performance through ion-assisted magnetron sputtering of TiN bottom electrodes

   https://doi.org/10.1038/s43246-025-00798-z  

   Bakhit, Babak; Hellenbrand, Markus; Tsai, Benson Kunhung; Choudhury, Abhijeet; Polcik, Peter; Kolozsvari, Szilard; Wang, Haiyan; Flewitt, Andrew J; MacManus-Driscoll, Judith L (December 2025, Communications Materials)

   Abstract Emerging non-volatile memristor-based devices with resistive switching (RS) materials are being widely researched as promising contenders for the next generation of data storage and neuromorphic technologies. Titanium nitride (TiN_x) is a common industry-friendly electrode system for RS; however, the precise TiN_xproperties required for optimum RS performance is still lacking. Herein, using ion-assisted DC magnetron sputtering, we demonstrate the key importance not only of engineering the TiN_xbottom electrodes to be dense, smooth, and conductive, but also understoichiometric in N. With these properties, RS in HfO₂-based memristive devices is shown to be optimised for TiN_0.96. These devices have switching voltages ≤ ±1 V with promising device-to-device uniformity, endurance, memory window of ~40, and multiple non-volatile intermediate conductance levels. This study highlights the importance of precise tuning of TiN_xbottom electrodes to achieve robust performance of oxide resistive switching materials. 

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4. Electron irradiation-induced defects for reliability improvement in monolayer MoS2-based conductive-point memory devices

   https://doi.org/10.1038/s41699-022-00306-8  

   Wu, Xiaohan; Gu, Yuqian; Ge, Ruijing; Serna, Martha I.; Huang, Yifu; Lee, Jack C.; Akinwande, Deji (May 2022, npj 2D Materials and Applications)

   Abstract Monolayer molybdenum disulfide has been previously discovered to exhibit non-volatile resistive switching behavior in a vertical metal-insulator-metal structure, featuring ultra-thin sub-nanometer active layer thickness. However, the reliability of these nascent 2D-based memory devices was not previously investigated for practical applications. Here, we employ an electron irradiation treatment on monolayer MoS₂film to modify the defect properties. Raman, photoluminescence, and X-ray photoelectron spectroscopy measurements have been performed to confirm the increasing amount of sulfur vacancies introduced by the e-beam irradiation process. The statistical electrical studies reveal the reliability can be improved by up to 1.5× for yield and 11× for average DC cycling endurance in the devices with a moderate radiation dose compared to unirradiated devices. Based on our previously proposed virtual conductive-point model with the metal ion substitution into sulfur vacancy, Monte Carlo simulations have been performed to illustrate the irradiation effect on device reliability, elucidating a clustering failure mechanism. This work provides an approach by electron irradiation to enhance the reliability of 2D memory devices and inspires further research in defect engineering to precisely control the switching properties for a wide range of applications from memory computing to radio-frequency switches. 

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5. Effects of Spent Coffee Grounds on Improvement of Resistive Switching Characteristics in Natural Rubber‐Based Memory

   https://doi.org/10.1002/smll.202504260  

   Awais, Muhammad; Othman, Nadras; Shafiq, Mohamad_Danial; Zhao, Feng; Cheong, Kuan_Yew (June 2025, Small)

   Abstract The recent upsurge in environmental awareness provokes the widespread usage of green materials in sustainable electronic applications. Herein, the effects of spent coffee grounds (SCGs) on natural rubber (NR)‐based resistive switching (RS) memory are systematically investigated. This study presents the fabrication of a metal‐insulator‐metal (MIM) structure using NR incorporated with SCGs (0 to 8 wt.%) as a memristive layer and sandwiched between electrodes. A significant improvement in the ON/OFF ratio from 10⁴for pure NR to 10⁷, read memory window increased from 2.03 to 2.45 V with improved stability even after 130 cycles of switching is achieved with the optimal concentration of SCGs (6 wt.%). The improved performance after the incorporation of SCGs is attributed to the introduction of key chemical functional groups (C═O, C═C) in the memristive film. By varying the viscosity of NR, bending of test structure, and voltage sweep rate, the effects of trap density and location on the RS performance are established. The RS mechanisms in high and low resistance states are dominated by space‐charge‐limited conduction and Ohm's law, respectively. This research manifests the potential of SCGs in improving the RS performance of bioorganic‐based memory devices. 

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