Biomaterial-Induced Stable Resistive Switching Mechanism in TiO₂ Thin Films: The Role of Active Interstitial Sites/Ions in Minimum Current Leakage and Superior Bioactivity

Abstract: Leakage of current in oxide layers is the main issue for higher speed and denser resistive random-access memory. Defect engineering played a substantial role in meeting this challenge by doping or producing controlled interstitial defects or active sites. These controlled active sites enabled memory cells to form a stable and reproducible conduction filament following an electrochemical metallization model. In this study, a defect-abundant lime peel extract (LPE)-mediated anatase TiO 2 t… Show more

“…4a (cross-sectional view, inset) depicts the uniform 300 nm pectin lm thickness deposited on the FTO substrate. Indeed, the uniform surface morphology along the thickness plays a crucial role in the stability of the conduction lament and avoids undesired current channels 3,16,42 . The thickness-dependent characteristics signicantly enhance the oxygen vacancies.…”

“…23,37,45 Furthermore, surface defects and roughness also play a decisive role in the leakage of the current or undesired current path. 3,16,42 If the number of surface defects and the surface roughness is high, then there is the possibility of the uncontrolled diffusion of the top electrode ions. 46,47 In order to avoid uncontrolled or undesired current channels, the surface roughness should be signicantly minimized.…”

“…In this vein, organic-based devices have aroused research interest owing to their inexpensive manufacturing, low power utilization, pure device fabrication, three-dimensional stacking potential, and multi-state ability for wearable and exible electronics. [1][2][3][4] However, the associated cons of noxious inorganic materials make their practical application challenging. In order to cope with this dilemma, the research community has toiled to explore capable nontoxic biomaterials that are eco-friendly, bioresorbable, biodegradable, biocompatible, and can be easily extracted.…”

“…[5][6][7][8][9][10] Previously, several manufactured optoelectronic devices have been reported using potential biomaterials for write-once and read many times and non-volatile transistor memory applications. [11][12][13][14] Additionally, resistive switching mechanism-based devices have also been fabricated by employing pectin, 15,16 tobacco mosaic virus, 17 ferritin protein, 18 lime peel, 3 2-amino-4,5-imidazoledicarbonitrile (AIDCN) 19 and cysteine. 20 In 2017, for the rst time, Sun et al introduced pectin as a memristor layer that can be degraded in deionized water in 10 minutes, but the high operational voltage needs some improvement.…”

“…21,22 Moreover, surface roughness also plays a decisive role in preventing undesired current paths that may lead to unstable conduction laments and high operational voltage. 3 In this contribution, various in situ experiments were carried out to minimize current leakage or prevent undesired current paths via surface defect engineering and the introduction of localized point defects within the insulating layer. These point defects act like a hopping charge carrier, minimize the leakage factor and provide a smooth tunable conductive path.…”

Green thin film for stable electrical switching in a low-cost washable memory device: proof of concept

“…4a (cross-sectional view, inset) depicts the uniform 300 nm pectin lm thickness deposited on the FTO substrate. Indeed, the uniform surface morphology along the thickness plays a crucial role in the stability of the conduction lament and avoids undesired current channels 3,16,42 . The thickness-dependent characteristics signicantly enhance the oxygen vacancies.…”

“…23,37,45 Furthermore, surface defects and roughness also play a decisive role in the leakage of the current or undesired current path. 3,16,42 If the number of surface defects and the surface roughness is high, then there is the possibility of the uncontrolled diffusion of the top electrode ions. 46,47 In order to avoid uncontrolled or undesired current channels, the surface roughness should be signicantly minimized.…”

“…In this vein, organic-based devices have aroused research interest owing to their inexpensive manufacturing, low power utilization, pure device fabrication, three-dimensional stacking potential, and multi-state ability for wearable and exible electronics. [1][2][3][4] However, the associated cons of noxious inorganic materials make their practical application challenging. In order to cope with this dilemma, the research community has toiled to explore capable nontoxic biomaterials that are eco-friendly, bioresorbable, biodegradable, biocompatible, and can be easily extracted.…”

“…[5][6][7][8][9][10] Previously, several manufactured optoelectronic devices have been reported using potential biomaterials for write-once and read many times and non-volatile transistor memory applications. [11][12][13][14] Additionally, resistive switching mechanism-based devices have also been fabricated by employing pectin, 15,16 tobacco mosaic virus, 17 ferritin protein, 18 lime peel, 3 2-amino-4,5-imidazoledicarbonitrile (AIDCN) 19 and cysteine. 20 In 2017, for the rst time, Sun et al introduced pectin as a memristor layer that can be degraded in deionized water in 10 minutes, but the high operational voltage needs some improvement.…”

“…21,22 Moreover, surface roughness also plays a decisive role in preventing undesired current paths that may lead to unstable conduction laments and high operational voltage. 3 In this contribution, various in situ experiments were carried out to minimize current leakage or prevent undesired current paths via surface defect engineering and the introduction of localized point defects within the insulating layer. These point defects act like a hopping charge carrier, minimize the leakage factor and provide a smooth tunable conductive path.…”

Green thin film for stable electrical switching in a low-cost washable memory device: proof of concept

Fundamentals and Applications of Raman‐Based Techniques for the Design and Development of Active Biomedical Materials

Antioxidant, and enhanced flexible nano porous scaffolds for bone tissue engineering applications