Impact of deposition temperature on the structural properties of CdS/Si nanoparticles for nanoelectronics

Hussein, Emad H.; Mohammed, Nadheer Jassim; Al-Fouadi, Anwar H. Ali; Abbas, Khaldoon N.; Alikhan, Jasim S.; Maksimova, Ksenia; Goikhman, Alexander

doi:10.1016/j.matlet.2019.07.088

Cited by 12 publications

(10 citation statements)

References 17 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This is because the quantum confinement effect present in the nano-sized semiconductor shows unique physical and chemical properties, such as size-dependent bandgap shifts Dris et al 2012;Sheng et al 2017). CdS have become one of the magnetic materials among the II-IV group semiconductor compounds due to its direct wider optical bandwidth of 2.42 eV at room temperature and the existing nonlinear optical properties (Abdel-Galil et al 2017;Ayodhya et al 2015;Hussein et al 2019;Landeros et al 2019;Martínez-Landeros et al 2019;Shkir et al 2020;Saxenaa et al 2018;Yang et al 2019). CdS nano-sized semiconductors have already been widely used as optical sensors, transistors, solar batteries, photo-electrocatalysis, as well as luminescence devices, laser, light-emitting diodes, detectors, and also in antibacterial activity (Göde, 2019;Hussein et al 2019;Ji et al, 2019;Martínez-Landeros et al 2019;Priya et al 2018;Saxenaa et al 2018;Sonker et al 2020;Yang et al 2019).…”

Section: Introductionmentioning

confidence: 99%

“…CdS have become one of the magnetic materials among the II-IV group semiconductor compounds due to its direct wider optical bandwidth of 2.42 eV at room temperature and the existing nonlinear optical properties (Abdel-Galil et al 2017;Ayodhya et al 2015;Hussein et al 2019;Landeros et al 2019;Martínez-Landeros et al 2019;Shkir et al 2020;Saxenaa et al 2018;Yang et al 2019). CdS nano-sized semiconductors have already been widely used as optical sensors, transistors, solar batteries, photo-electrocatalysis, as well as luminescence devices, laser, light-emitting diodes, detectors, and also in antibacterial activity (Göde, 2019;Hussein et al 2019;Ji et al, 2019;Martínez-Landeros et al 2019;Priya et al 2018;Saxenaa et al 2018;Sonker et al 2020;Yang et al 2019). CdS is also an n-type semiconducting material and acts as a window layer for solar cell fabrication due to its high value of transmittance and band gap width (Martínez-Landeros et al, 2019;Shkir et al 2020).…”

Section: Introductionmentioning

confidence: 99%

“…Previously, tremendous attempts have been devoted to yielding nanoparticles with improved structural and physical properties (Yang et al, 2019). Hence, various physical and chemical methods have been proposed to produce the metal sulfides nanoparticles, such as the hydrothermal, solvothermal, precipitation, colloidal, sonochemical, and biosynthesis and sol-gel methods (Ayodhya & Veerabhadram, 2019;Dris et al 2013;Hussein et al 2019;Mohamed et al 2020;Priya et al 2018;Sonker et al 2020;Wilson & Ahamed, 2019;Yang et al 2019). The nanomaterial properties could be perfectly adjusted by the shape and morphology to meet the requirement and performance of the final product (Saxenaa et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Thermally driven structural phase transformation and dislocation density of CdS nanoparticles precipitated without surfactant in KOH alkaline medium

Sheng

Alrababah

2021

KJS publishes peer-review articles in Mathematics, Computer Sci

View full text Add to dashboard Cite

The present research demonstrates a detailed discussion for the effect of annealing temperature on the structural transformation and surface morphology of the CdS nanoparticles synthesized using the precipitation method without surfactant in KOH alkaline medium. The annealing temperature used was in the range of 160 – 480 oC. The samples structural, functional group and morphological properties were investigated by using XRD, FTIR and SEM techniques. XRD analysis reveals that the CdS has gradually been transformed from the pure cubic to hexagonal polycrystalline structure as well as improved crystallinity upon increasing the temperature. Besides, the parameters of average crystallite size and dislocation density were calculated using the established Debye- Scherrer equation. The average crystallite size was in nano-dimension and increases gradually with temperature. The FTIR spectra indicate that the characteristic vibration band of CdS emerged in the lower wavenumber region of 650 and 500 cm-1, and the band becomes stronger as the temperature rises. Also, the SEM images demonstrate that the CdS exhibits uniform spherical morphology and the particle size grows larger at elevated temperatures. The improved crystallinity and structural properties tuning ability against temperature allows beneficial optical applications as solar cells, photocatalysts, non-linear optics, light emitting diodes and optoelectronic devices.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Thermally driven structural phase transformation and dislocation density of CdS nanoparticles precipitated without surfactant in KOH alkaline medium

Sheng

Alrababah

2021

KJS publishes peer-review articles in Mathematics, Computer Sci

View full text Add to dashboard Cite

show abstract

“…Hayden et al were the first to report the fabrication of heterostructured nanowires with p‐type Si core and n‐type CdS shell using pulsed‐laser deposition (PLD) for the application as nano LEDs in 2005 [8,9] . Subsequently, there has been quite a few reports involving the application of CdS/Si heterojunction as photodetector [10–18] . A recent work by Lin et al reported the synthesis of CdS quantum dot (QD) decorated vertically aligned Si NWs arrays with enhanced activity and recyclable operability for photocatalytic hydrogen evolution [19] .…”

Section: Introductionmentioning

confidence: 99%

“…[8,9] Subsequently, there has been quite a few reports involving the application of CdS/Si heterojunction as photodetector. [10][11][12][13][14][15][16][17][18] A recent work by Lin et al reported the synthesis of CdS quantum dot (QD) decorated vertically aligned Si NWs arrays with enhanced activity and recyclable operability for photocatalytic hydrogen evolution. [19] The formation of p-n heterojunction at the interface of the Si NWs and the CdS QDs results in an internal electric field which facilitate the separation and transport of the photoinduced charge carriers thereby improving both the photoactivity and photostability of the Si NWs/CdS array composite.…”

Section: Introductionmentioning

confidence: 99%

Electricity Generation from Atmospheric Moisture Using a CdS/p‐Si Nanowire Hetero‐Junction Device

et al. 2022

View full text Add to dashboard Cite

One‐dimensional heterojunction devices are gaining attention because of improved carrier collection which results in improving the overall efficiency of a device. Herein, we report the synthesis of a CdS/p‐Si nanowire (NW) hetero‐junction device by wet‐chemical methods and their potential application for electricity generation from atmospheric moisture. A single CdS/p‐Si NWs hetero‐junction based moisture enabled electricity generator (MEG) device exhibits a saturated maximum output voltage in the range of 250–300 mV and a saturation current of ∼0.2 μA in presence of humid conditions. This primitive module acts as a promising candidate for future energy generation devices constituting of individual units connected either through simple series or parallel connection to scale up high electrical power.

show abstract

PbS/p‐Si NW Heterojunction Thin Film Device for Room Temperature NH₃ Detection

Aggarwal,

Kumar,

Jain

et al. 2023

ChemistrySelect

View full text Add to dashboard Cite

One dimensional heterostructures with a definite interface where the host particle is decorated with the secondary material have been widely exploited for photocatalysis because of increased efficiency. Herein we report the synthesis of PbS−Si NW heterojunction using low temperature chemical bath deposition (CBD) techniques. Temperature, time, and the complexing agents of the growth solution were optimized to control the morphology and the resultant properties of the heterojunction thin films. These synthesized thin films exhibit high sensor responses in the presence of ammonia (NH3) due to an increase in the surface area and efficient p‐n junction formation. Additionally, there is a vast improvement in the detection limit of the sensors as our device was found to respond at concentrations as low as 0.1 ppm. Growth conditions are found to have significant influence on the sensor response.

show abstract

Impact of deposition temperature on the structural properties of CdS/Si nanoparticles for nanoelectronics

Cited by 12 publications

References 17 publications

Thermally driven structural phase transformation and dislocation density of CdS nanoparticles precipitated without surfactant in KOH alkaline medium

Thermally driven structural phase transformation and dislocation density of CdS nanoparticles precipitated without surfactant in KOH alkaline medium

Electricity Generation from Atmospheric Moisture Using a CdS/p‐Si Nanowire Hetero‐Junction Device

PbS/p‐Si NW Heterojunction Thin Film Device for Room Temperature NH₃ Detection

Contact Info

Product

Resources

About

Impact of deposition temperature on the structural properties of CdS/Si nanoparticles for nanoelectronics

Cited by 12 publications

References 17 publications

Thermally driven structural phase transformation and dislocation density of CdS nanoparticles precipitated without surfactant in KOH alkaline medium

Thermally driven structural phase transformation and dislocation density of CdS nanoparticles precipitated without surfactant in KOH alkaline medium

Electricity Generation from Atmospheric Moisture Using a CdS/p‐Si Nanowire Hetero‐Junction Device

PbS/p‐Si NW Heterojunction Thin Film Device for Room Temperature NH3 Detection

Contact Info

Product

Resources

About

PbS/p‐Si NW Heterojunction Thin Film Device for Room Temperature NH₃ Detection