Promising novel transparent conductive F-doped ZnSnO3 thin films for optoelectronic applications

Radaf, I.M. El

doi:10.1007/s10854-022-09600-z

Cited by 11 publications

(4 citation statements)

References 62 publications

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“…Furthermore, the Li-doped ZTO 3 layers' , 1 χ ( ) , 3 χ ( ) and n 2 magnitudes are all roughly larger than those of previous semiconductors that have been recorded. 37,48 Hot-probe instrument of the Li-doped ZTO 3 films.-A hot probe apparatus was required to determine the type of semiconductor. The hot probe gadget measures p-type conductivity in the Li-doped ZTO 3 films.…”

Section: Resultsmentioning

confidence: 99%

“…They noted that the fluorine doping addition improves the electrical conductivity, optical carrier concentration, optical conductivity, and optical mobility of the ZTO 3 thin films. 37 The goal of the current study is to create innovative Li-doped ZTO 3 layers by spray pyrolysis and address the impact of Li doping content on the optical, optoelectrical, and structural properties of the Li-doped ZTO 3 layers.…”

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confidence: 99%

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Effect of Li Doping on Structural, Optical, and Optoelectrical Characteristics of ZnSnO₃ Thin Films Prepared by Nebulizer Spray Pyrolysis

Alkhamisi

2024

ECS J. Solid State Sci. Technol.

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In this work, ZnSnO3 (ZTO3) and Li-doped ZTO3 thin films were synthesized on glass slides by a cost-effective nebulizer spray pyrolysis procedure. The X-ray diffraction analysis revealed that the ZTO3 and Li-doped ZTO3 thin films possessed a rhombohedral structure. The structural indices (grain size, dislocation density, lattice strain) of the ZTO3 and Li-doped ZTO3 thin films were computed. The morphology characteristics of the ZTO3 and Li-doped ZTO3 thin films were observed by field emission scanning electron microscopy. The inspected films display uniform and homogeneous surfaces. The optical transmittance, T, and reflectance, R, of the ZTO3 and Li-doped ZTO3 thin films were recorded using a double-beam spectrophotometer to investigate the optical characteristics of these layers. The refractive index of the ZTO3 and Li-doped ZTO3 thin films was enhanced via the Li content increase. Moreover, Tauc’s plots demonstrated that the energy gap of the ZTO3 and Li-doped ZTO3 thin films was reduced from 3.85 eV to 3.08 eV by boosting the Li doping content. Moreover, the increase in Li content produces an enhancement in the optoelectrical indices (optical resistivity, optical carrier concentration, optical mobility, plasms frequency, and optical conductivity) of the ZTO3 and Li-doped ZTO3 thin films. The nonlinear optical indices of the ZTO3 and Li-doped ZTO3 thin films were deduced, and it was noted that Li content boosted the nonlinear optical indices of these layers. All the ZTO3 and Li-doped ZTO3 thin films displayed n-type semiconducting properties by the hot probe equipment.

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Section: Resultsmentioning

confidence: 99%

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confidence: 99%

Effect of Li Doping on Structural, Optical, and Optoelectrical Characteristics of ZnSnO₃ Thin Films Prepared by Nebulizer Spray Pyrolysis

Alkhamisi

2024

ECS J. Solid State Sci. Technol.

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“…[5][6][7] Among them, nanostructures of ZnSnO 3 (various nano shapes, such as wires, rods, rings, tubes, cubes, and spheres) have attracted considerable interest owing to their advantageous chemical sensitivity, wide energy bandgap, high transmittance percentage, electron mobility, low price, non-toxicity, and earth abundance. 5,[8][9][10][11][12][13] The performance of energy storage devices and catalysis is greatly affected by the morphology, structure, and physical characteristics of the active electrode materials. Furthermore, LN-type ZnSnO 3 , which possesses a high spontaneous polarization (theoretical value P r z 59 mC cm −2 ), has been experimentally observed in epitaxial thin lms with a value of P r z 47 mC cm −2 .…”

Section: Introductionmentioning

confidence: 99%

“…Accordingly, to overcome this limitation and improve their characteristics, researchers are actively engaged in the development of ternary oxides, such as ZnSnO 3 and In-Zn-O. [5][6][7] Among them, nanostructures of ZnSnO 3 (various nano shapes, such as wires, rods, rings, tubes, cubes, and spheres) have attracted considerable interest owing to their advantageous chemical sensitivity, wide energy bandgap, high transmittance percentage, electron mobility, low price, non-toxicity, and earth abundance. 5,[8][9][10][11][12][13] The performance of energy storage devices and catalysis is greatly affected by the morphology, structure, and physical characteristics of the active electrode materials.…”

Section: Introductionmentioning

confidence: 99%

Comprehensive review of micro/nanostructured ZnSnO₃: characteristics, synthesis, and diverse applications

Rahman,

Bashar,

Rahman

et al. 2023

RSC Adv.

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A Spectroscopic Correlative Analysis of Eu³⁺‐Substituted Zn_1‐_xSnO₃ Nano Phosphors for Anticounterfeiting Applications

Albert,

Velladurai

2024

Part & Part Syst Charact

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A series of orange–red phosphors Zn1‐xSnO3:xEu3+ synthesized using a sol–gel combustion process is used to study the modified local crystal structure by site‐selective substitution of Eu3+ ions. XRD with the Rietveld refinement analysis reveals an orthorhombic ZnSnO3 structure with a space group 61. SEM and TEM with EDAX analyses confirm the flower‐like morphology of Zn1‐xSnO3:xEu3+ nanorods. Photoluminescence (PL) spectroscopy gives substantial confirmation for the inclusion of Eu3+ ions into the ZnSnO3 host. Judd‐Ofelt analysis confirms the substitution of Eu3+ ion in an asymmetric environment in ZnSnO3, which is responsible for orange–red emission at 615 nm. UV–vis–DRS analysis shows that the addition of Eu3+ ions (1% to 17% in phases of 4%) results in the formation of confined energy states with an increased band gap from 2.78 to 3.29 eV. The ability of ZnSnO3 to host Eu3+ ions signifies that it can be used as an effective luminescent material. Cyclic voltammetry analysis reveals the enhanced charge separation in Zn1‐xSnO3:xEu3+(13%) nanophosphor. The optimized Zn1‐xSnO3:xEu3+(13%) nano phosphor mixed with silicone investigated for the generation of anti‐counterfeiting patterns indicates its potential to generate high‐resolution image patterns on various surfaces under monochromatic UV or visible‐LASER LED illumination.

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Promising novel transparent conductive F-doped ZnSnO3 thin films for optoelectronic applications

Cited by 11 publications

References 62 publications

Effect of Li Doping on Structural, Optical, and Optoelectrical Characteristics of ZnSnO₃ Thin Films Prepared by Nebulizer Spray Pyrolysis

Effect of Li Doping on Structural, Optical, and Optoelectrical Characteristics of ZnSnO₃ Thin Films Prepared by Nebulizer Spray Pyrolysis

Comprehensive review of micro/nanostructured ZnSnO₃: characteristics, synthesis, and diverse applications

A Spectroscopic Correlative Analysis of Eu³⁺‐Substituted Zn_1‐_xSnO₃ Nano Phosphors for Anticounterfeiting Applications

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Promising novel transparent conductive F-doped ZnSnO3 thin films for optoelectronic applications

Cited by 11 publications

References 62 publications

Effect of Li Doping on Structural, Optical, and Optoelectrical Characteristics of ZnSnO3 Thin Films Prepared by Nebulizer Spray Pyrolysis

Effect of Li Doping on Structural, Optical, and Optoelectrical Characteristics of ZnSnO3 Thin Films Prepared by Nebulizer Spray Pyrolysis

Comprehensive review of micro/nanostructured ZnSnO3: characteristics, synthesis, and diverse applications

A Spectroscopic Correlative Analysis of Eu3+‐Substituted Zn1‐xSnO3 Nano Phosphors for Anticounterfeiting Applications

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Effect of Li Doping on Structural, Optical, and Optoelectrical Characteristics of ZnSnO₃ Thin Films Prepared by Nebulizer Spray Pyrolysis

Effect of Li Doping on Structural, Optical, and Optoelectrical Characteristics of ZnSnO₃ Thin Films Prepared by Nebulizer Spray Pyrolysis

Comprehensive review of micro/nanostructured ZnSnO₃: characteristics, synthesis, and diverse applications

A Spectroscopic Correlative Analysis of Eu³⁺‐Substituted Zn_1‐_xSnO₃ Nano Phosphors for Anticounterfeiting Applications