Porous-Spherical Cr2O3-Cr(OH)3-Polypyrrole/Polypyrrole Nanocomposite Thin-Film Photodetector and Solar Cell Applications

Rabia, Mohamed; Trabelsi, Amira Ben Gouider; Elsayed, Asmaa M.; Alkallas, Fatemah H.

doi:10.3390/coatings13071240

Cited by 7 publications

(2 citation statements)

References 55 publications

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“…As the optical wavelength increases, this responsiveness gradually diminishes. This trend is evident in the R and D values [34,35], showcasing optimal performance at 340 nm with values of 0.49 mA.W −1 and 1.1 × 10 8 Jones, respectively. Both R and D values consider these key metrics to play a pivotal role in assessing the overall performance of photodetectors.…”

Section: Electrical Testingmentioning

confidence: 81%

Fabrication of thin film solar cell based on CoO-CoS/P2-Amino-1-mercaptobenzene/polypyrrole with additional promising sensitivities to photons in a broad optical region

Madkhali,

Rabia

2024

Phys. Scr.

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The production of a thin-film solar cell device, employing CoO-CoS/P2-Amino-1-mercaptobenzene/polypyrrole (CoO-CoS-P2AMB/Ppy), showcases enhanced sensitivity across a broad optical spectrum. This achievement is realized through a one-pot polymerization process involving 2-Amino-1-mercaptobenzene, Co(NO3)2, and K2S2O8. Notably, the polymerization reaction incorporates the inclusion of a Ppy seeding layer into the solution.To comprehensively characterize the synthesized materials, an array of analytical tools is employed. Subsequently, the CoO-CoS-P2AMB/Ppy device undergoes rigorous testing under diverse light conditions, including darkness, white light, and monochromatic light. These conditions aim to assess the device's responsiveness to photons of varying energies, where the resulting current density (Jph) serves as an indicator of generated hot electrons and the overall efficiency of the fabricated device.At a potential of 2.0 V, the measured values for Jph and dark current (Jo) stand at 0.11 and 0.04 mA.cm-2, respectively. The solar cell characteristics are further evaluated through measured values for JSC (-0.01 µA.cm-2) and VOC (0.038 V), reflecting the device's performance under solar testing conditions.In addition to its solar cell attributes, the device exhibits light-sensing behavior, quantified through calculated photoresponsivity (R) and detectivity (D) values. These values, obtained under various monochromatic lights, amount to 0.49 mA.W-1 and 1.1x108 Jones, respectively.The exceptional performance of the CoO-CoS-P2AMB/Ppy thin-film solar cell device, coupled with its light-sensing capabilities, positions the device as a promising candidate for commercial applications. Its potential extends to the fabrication of cost-effective thin-film sensing devices, presenting opportunities for widespread utilization in various industries.

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Section: Electrical Testingmentioning

confidence: 81%

Fabrication of thin film solar cell based on CoO-CoS/P2-Amino-1-mercaptobenzene/polypyrrole with additional promising sensitivities to photons in a broad optical region

Madkhali,

Rabia

2024

Phys. Scr.

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“…Our group works on photodetector based on polymer composite [22][23][24][25], in which these photodetectors based on conductive polymers offer numerous advantages over their traditional metal-based counterparts. Conductive polymers can be processed through solution-based methods, allowing for the convenient and costeffective fabrication of devices on flexible substrates.…”

Section: Introductionmentioning

confidence: 99%

One pot synthesizing of cobalt (III) and (IV) oxides/polypyrrole nanocomposite for light sensing in wide optical range

Rabia,

Ben Gouider Trabelsi,

Alkallas

et al. 2024

Phys. Scr.

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A highly porous potato-shaped nanocomposite, Co(111) and Co(IV) oxide/polypyrrole (Co2O3-Co3O4/Ppy), is synthesized employing a one-pot procedure involving the slow oxidation of pyrrole using Co(NO3)2. The exceptional physical characteristics of this nanocomposite are accompanied by impressive optical properties, marked by a bandgap of 1.72 eV. Its absorbance spans across the UV, visible (Vis), and infrared (IR) regions, making it a promising candidate for optoelectronic applications such as photodetectors designed for light sensing within this extensive optical range that encompasses a substantial portion of the electromagnetic spectrum.This Co2O3-Co3O4/Ppy thin film photodetector is subjected to electrical testing under varying light conditions, leading to the determination of the photocurrent density (Jph) value of 0.26 mA.cm-2. When evaluated under different monochromatic light sources ranging from 340 to 730 nm, distinct Jph values are observed for each wavelength, reflecting the nanocomposite's ability to effectively interact with photons across this spectrum. The measured responsivity (R) and detectivity (D) values further underscore the photodetector's efficiency. At 340 nm, the R and D values stand at 1.22 mA.W-1 and 0.275x109 Jones, respectively. Similarly, at 730 nm, these values are 1.21 mA.W-1 and 0.270x109 Jones. The combination of these favorable findings, including cost-effectiveness and high stability, position the Co2O3-Co3O4/Ppy nanocomposite as an optimal choice for a wide range of industrial applications, attesting to its potential impact in the field.

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Tungsten oxide‐iodide/poly‐2‐aminobenzenethiol nanocomposite with iodine intercalation as a promising electrode for potentiometric sensing of Pb²⁺ ions in water

Alnuwaiser,

Rabia

2024

Env Prog and Sustain Energy

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Tungsten oxide‐iodide/poly‐2‐aminobenzenethiol nanocomposite (WO2I2/P2ABT) is created through the introduction of iodine into polymer chains, where iodine serves as an oxidizing agent during the synthesis process. With a highly porous structure, the sensing capabilities of WO2I2/P2ABT for detecting Pb2+ ions are successfully demonstrated, revealing a Nernstian slope of 26.2 mV/decade. This detection is accomplished through a simple potentiometric technique, employing a simple two‐electrode cell setup. To further validate its performance, cyclic voltammetry is conducted using a three‐electrode system, revealing a remarkable sensitivity of 7.2 × 10−5 A M−1 for Pb2+ ions. The nanocomposite sensor's selectivity is rigorously examined by subjecting it to testing in the presence of 0.01 M interfering ions. The results unequivocally demonstrate that the sensor remains unresponsive to these interfering ions, underscoring its remarkable selectivity for Pb2+ ions. Moreover, the sensor's behavior is evaluated under real‐world conditions using natural samples, where, no indications of interference from other ions are observed. This is estimated by the absence of cyclic peaks in the voltammogram, indicating the sensor's unique ability to selectively detect Pb2+ ions without being perturbed by other ions that may be naturally occurring in the samples. These findings emphasize the nanocomposite sensor's potential for a wide array of applications in environmental monitoring and analytical chemistry. Its extraordinary combination of high sensitivity, impeccable selectivity, and robust performance in practical scenarios establishes it as an invaluable tool for detecting Pb2+ ions across various contexts.

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Porous-Spherical Cr2O3-Cr(OH)3-Polypyrrole/Polypyrrole Nanocomposite Thin-Film Photodetector and Solar Cell Applications

Cited by 7 publications

References 55 publications

Fabrication of thin film solar cell based on CoO-CoS/P2-Amino-1-mercaptobenzene/polypyrrole with additional promising sensitivities to photons in a broad optical region

Fabrication of thin film solar cell based on CoO-CoS/P2-Amino-1-mercaptobenzene/polypyrrole with additional promising sensitivities to photons in a broad optical region

One pot synthesizing of cobalt (III) and (IV) oxides/polypyrrole nanocomposite for light sensing in wide optical range

Tungsten oxide‐iodide/poly‐2‐aminobenzenethiol nanocomposite with iodine intercalation as a promising electrode for potentiometric sensing of Pb²⁺ ions in water

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Porous-Spherical Cr2O3-Cr(OH)3-Polypyrrole/Polypyrrole Nanocomposite Thin-Film Photodetector and Solar Cell Applications

Cited by 7 publications

References 55 publications

Fabrication of thin film solar cell based on CoO-CoS/P2-Amino-1-mercaptobenzene/polypyrrole with additional promising sensitivities to photons in a broad optical region

Fabrication of thin film solar cell based on CoO-CoS/P2-Amino-1-mercaptobenzene/polypyrrole with additional promising sensitivities to photons in a broad optical region

One pot synthesizing of cobalt (III) and (IV) oxides/polypyrrole nanocomposite for light sensing in wide optical range

Tungsten oxide‐iodide/poly‐2‐aminobenzenethiol nanocomposite with iodine intercalation as a promising electrode for potentiometric sensing of Pb2+ ions in water

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Tungsten oxide‐iodide/poly‐2‐aminobenzenethiol nanocomposite with iodine intercalation as a promising electrode for potentiometric sensing of Pb²⁺ ions in water