Review on resistive switching mechanisms of bio-organic thin film for non-volatile memory application

Cheong, Kuan Yew; Tayeb, Ilias Ait; Zhao, Feng; Abdullah, Jafri Malin

doi:10.1515/ntrev-2021-0047

Cited by 46 publications

(43 citation statements)

References 93 publications

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“…Changes in the 10-mV range have been reported for biomolecules adsorbed on different surfaces and forming thin layers [ 58 ]. The carrier conduction process depends on the work function differences of LTO and graphene and LUMO and HOMO of the PLL thin film [ 59 ], suggesting a conductivity change in the system.…”

Section: Resultsmentioning

confidence: 99%

Application of Poly-L-Lysine for Tailoring Graphene Oxide Mediated Contact Formation between Lithium Titanium Oxide LTO Surfaces for Batteries

et al. 2022

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When producing stable electrodes, polymeric binders are highly functional materials that are effective in dispersing lithium-based oxides such as Li4Ti5O12 (LTO) and carbon-based materials and establishing the conductivity of the multiphase composites. Nowadays, binders such as polyvinylidene fluoride (PVDF) are used, requiring dedicated recycling strategies due to their low biodegradability and use of toxic solvents to dissolve it. Better structuring of the carbon layers and a low amount of binder could reduce the number of inactive materials in the electrode. In this study, we use computational and experimental methods to explore the use of the poly amino acid poly-L-lysine (PLL) as a novel biodegradable binder that is placed directly between nanostructured LTO and reduced graphene oxide. Density functional theory (DFT) calculations allowed us to determine that the (111) surface is the most stable LTO surface exposed to lysine. We performed Kubo–Greenwood electrical conductivity (KGEC) calculations to determine the electrical conductivity values for the hybrid LTO–lysine–rGO system. We found that the presence of the lysine-based binder at the interface increased the conductivity of the interface by four-fold relative to LTO–rGO in a lysine monolayer configuration, while two-stack lysine molecules resulted in 0.3-fold (in the plane orientation) and 0.26-fold (out of plane orientation) increases. These outcomes suggest that monolayers of lysine would specifically favor the conductivity. Experimentally, the assembly of graphene oxide on poly-L-lysine-TiO2 with sputter-deposited titania as a smooth and hydrophilic model substrate was investigated using a layer-by-layer (LBL) approach to realize the required composite morphology. Characterization techniques such as X-ray photoelectron spectroscopy (XPS), atomic force microscopy (AFM), Kelvin probe force microscopy (KPFM), scanning electron microscopy (SEM) were used to characterize the formed layers. Our experimental results show that thin layers of rGO were assembled on the TiO2 using PLL. Furthermore, the PLL adsorbates decrease the work function difference between the rGO- and the non-rGO-coated surface and increased the specific discharge capacity of the LTO–rGO composite material. Further experimental studies are necessary to determine the influence of the PLL for aspects such as the solid electrolyte interface, dendrite formation, and crack formation.

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Section: Resultsmentioning

confidence: 99%

Application of Poly-L-Lysine for Tailoring Graphene Oxide Mediated Contact Formation between Lithium Titanium Oxide LTO Surfaces for Batteries

et al. 2022

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“…Based on the slope at region A, it can be concluded that either a trap‐fill limited and/or a trap‐free conduction mechanism dominates in the low voltage region. [ 6,15 ] It is highly possible that due to the incorporation of C60, carriers can be consistently trapped by C60 and contributed to a higher resistance with a less steep slope as shown in region A. At higher voltages in region B, the conduction of carriers is governed by a trap‐fill limited conduction mechanism, which is similar to carrier conduction in the bulk polymannose thin film without C60.…”

Section: Resultsmentioning

confidence: 99%

“…Hence, an interlocking effect of C60 with polymmanose may contribute to the reduction of V SET as the concentration of C60 increases. It is unlikely that the conductive paths are metallic as the formation of these metallic filaments must be initiated by a redox reaction from TE, [ 6,16 ] but in this work an inert electrode was used.…”

Section: Resultsmentioning

confidence: 99%

“…[1][2][3][4] Their performances [5] are not comparable with typical inorganic-based counterparts but with their unique properties such as the ease of processing and environmental friendliness provide a great opportunity for bioorganic materials to be explored. Various bioorganic materials [6] have been used to form the active layers for this application. Of these, polymannose, one of plant-based polysaccharides, has been recently reported [7] with encouraging resistive switching performance.…”

Section: Introductionmentioning

confidence: 99%

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

Cheong

Tayeb

Zhao

2022

Physica Rapid Research Ltrs

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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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“…This behavior allows the use of these devices for the implementation of artificial neuronal synapses in neuromorphic systems, since the synaptic weight between two neurons can be electrically adjusted [5]. Various materials have been studied as resistive switching devices, such as perovskites [6], manganites [7], and even organic materials [8]. However, metal oxides are the most widely studied materials [9].…”

Section: Introductionmentioning

confidence: 99%

Influences of the Temperature on the Electrical Properties of HfO2-Based Resistive Switching Devices

et al. 2021

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In the attempt to understand the behavior of HfO2-based resistive switching devices at low temperatures, TiN/Ti/HfO2/W metal–insulator–metal devices were fabricated; the atomic layer deposition technique was used to grow the high-k layer. After performing an electroforming process at room temperature, the device was cooled in a cryostat to carry out 100 current–voltage cycles at several temperatures ranging from the “liquid nitrogen temperature” to 350 K. The measurements showed a semiconducting behavior in high and low resistance states. In the low resistance state, a hopping conduction mechanism was obtained. The set and reset voltages increased when temperature decreased because the thermal energies for oxygen vacancies and ions were reduced. However, the temperature did not influence the power absorbed in the reset transition, indicating the local temperature in the filament controls the transition. The set transition turned from gradual to abrupt when decreasing the temperature, due to a positive feedback between the current increase and the Joule heating at low temperatures.

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Review on resistive switching mechanisms of bio-organic thin film for non-volatile memory application

Cited by 46 publications

References 93 publications

Application of Poly-L-Lysine for Tailoring Graphene Oxide Mediated Contact Formation between Lithium Titanium Oxide LTO Surfaces for Batteries

Application of Poly-L-Lysine for Tailoring Graphene Oxide Mediated Contact Formation between Lithium Titanium Oxide LTO Surfaces for Batteries

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

Influences of the Temperature on the Electrical Properties of HfO2-Based Resistive Switching Devices

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