Synthesis of ZnSe and ZnSe:Cu quantum dots by a room temperature photochemical (UV‐assisted) approach using Na<sub>2</sub>SeO<sub>3</sub> as Se source and investigating optical properties

Khafajeh, R.; Molaei, M.; Karimipour, Masoud

doi:10.1002/bio.3224

Cited by 24 publications

(12 citation statements)

References 41 publications

(62 reference statements)

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“…The PL spectrum of QDs is a broad emission spectrum with three peaks located at 400 nm, 435 nm and 460 nm. Such phenomenon had been reported by previous investigation [35] . The first peak at 400 nm is attributed to band gap emission.…”

Section: Resultssupporting

confidence: 87%

ZnSe quantum dots downshifting layer for perovskite solar cells

Wang

Shen

et al. 2018

Journal of Energy Chemistry

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a b s t r a c tTo date, the instability of organometal halide perovskite solar cells (PSCs) has become the focus issue that limits the development and long-term application of PSCs. Both the ultraviolet (UV) rays in sunlight and moisture in air can significantly accelerate the disintegration of the perovskite. Here, we introduced a ZnSe quantum dots layer as downshifting materials, which was spin-coated onto the backside of PSCs. This layer converted the UV rays into visible light to prevent the destruction of PSCs as well as increase the light harvesting of the perovskite layer. Under the UV irradiation in the moisture ambient (40%), the destruction speed of the unencapsulated perovskite films were also delayed evidently. In addition, the power conversion efficiency (PCE) of the PSCs was increased from 16.6% to 17.3% due to the increase of the visible light absorbance of the perovskite.

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Section: Resultssupporting

confidence: 87%

ZnSe quantum dots downshifting layer for perovskite solar cells

Wang

Shen

et al. 2018

Journal of Energy Chemistry

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“…[52] The band at 1645 cm À 1 is attributed to the COO À bonds. [53] Raman spectra represent the structural data about the sample in the form of chemical bonds and atomic rearrangements. The Raman spectra of CuZnSe-1, 2 samples are shown in Figure 2(d).…”

Section: Structural Analysis: Xrd Ftir and Ramanmentioning

confidence: 99%

Hydrothermal Synthesis of Cu_0.66‐xZn_0.34+xSe Materials and Investigation of Their Structural, Optical, and Magnetic Properties

Parida,

Senapati,

Pradhan

et al. 2023

ChemistrySelect

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In the current paper, we have prepared Cu0.66‐xZn0.34+xSe materials by varying the concentration of copper and zinc (x=0, 0.085, 0.17, 0.255, 0.34) with the help of a facile one‐step hydrothermal method. The X‐ray diffraction study reveals that the as‐prepared nanomaterials show the polycrystalline property. The crystallinity increases with the variation of Zn concentration, and the average crystallite size was calculated in the 39 to 55 nm range. The morphological analysis shows the uniform and agglomerated particles having an average size of around 596 nm. High‐resolution transmission electron microscopy and selected area electron diffraction study reveal the crystalline phases of the prepared sample. The energy‐dispersive X‐ray analysis confirmed the presence of constituent elements in the sample. The sample shows a high optical bandgap in the range of 3.6 eV to 4.09 eV, which was calculated from absorbance spectra. Photoluminescence measurements of the samples were carried out with 532 nm laser excitation, where the defect‐related emission peaks in the 540–850 nm range are observed. A change in the bandgap and optical emission is observed for different compositions. The magnetic properties analysis through the vibrating sample magnetometer reveals that the prepared sample exhibits ferromagnetic behaviour at room temperature, which can be used in magnetic storage applications. The tuning of the optical properties of the samples by varying the copper and zinc concentrations will be useful for various photonic devices.

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“…The uniform size of the QDs was achieved using the HI method, which absorbed significant amounts of UV light and converted it into visible light. The emission spectra contained three different peaks at 400 nm, 435 nm, and 460 nm, which were attributed to the bandgap emission, surface trap state, and deep level state of the QDs, respectively [ 197 ]. The results revealed that the cell with QDs exhibited a PCE of 17.3% as well as better stability compared to the cell without QDs.…”

Section: Qds With Various Solar Cellsmentioning

confidence: 99%

Recent Advances in Colloidal Quantum Dots or Perovskite Quantum Dots as a Luminescent Downshifting Layer Embedded on Solar Cells

et al. 2022

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The solar cell has a poor spectral response in the UV region, which affects its power conversion efficiency (PCE). The utilization of a luminescent downshifting (LDS) layer has been suggested to improve the spectral response of the photovoltaics in the short wavelength region through photoluminescence (PL) conversion and antireflection effects, which then enhance the PCE of the solar cell. Recently, colloidal quantum dots (CQDs) or perovskite quantum dots (PQDs) have been gaining prime importance as an LDS material due to their eminent optical characteristics, such as their wide absorption band, adjustable visible emission, short PL lifetime, and near-unity quantum yields. However, the instability of QDs that occurs under certain air, heat, and moisture conditions limits its commercialization. Thus, in this review, we will focus on the physical and optical characteristics of QDs. Further, we will discuss different synthesis approaches and the stability issues of QDs. Different approaches to improve the stability of QDs will be discussed in detail alongside the recent breakthroughs in QD-based solar cells for various applications and their current challenges. We expect that this review will provide an effective gateway for researchers to fabricate LDS-layer-based solar cells.

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Synthesis of ZnSe and ZnSe:Cu quantum dots by a room temperature photochemical (UV‐assisted) approach using Na₂SeO₃ as Se source and investigating optical properties

Cited by 24 publications

References 41 publications

ZnSe quantum dots downshifting layer for perovskite solar cells

ZnSe quantum dots downshifting layer for perovskite solar cells

Hydrothermal Synthesis of Cu_0.66‐xZn_0.34+xSe Materials and Investigation of Their Structural, Optical, and Magnetic Properties

Recent Advances in Colloidal Quantum Dots or Perovskite Quantum Dots as a Luminescent Downshifting Layer Embedded on Solar Cells

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Synthesis of ZnSe and ZnSe:Cu quantum dots by a room temperature photochemical (UV‐assisted) approach using Na2SeO3 as Se source and investigating optical properties

Cited by 24 publications

References 41 publications

ZnSe quantum dots downshifting layer for perovskite solar cells

ZnSe quantum dots downshifting layer for perovskite solar cells

Hydrothermal Synthesis of Cu0.66‐xZn0.34+xSe Materials and Investigation of Their Structural, Optical, and Magnetic Properties

Recent Advances in Colloidal Quantum Dots or Perovskite Quantum Dots as a Luminescent Downshifting Layer Embedded on Solar Cells

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Synthesis of ZnSe and ZnSe:Cu quantum dots by a room temperature photochemical (UV‐assisted) approach using Na₂SeO₃ as Se source and investigating optical properties

Hydrothermal Synthesis of Cu_0.66‐xZn_0.34+xSe Materials and Investigation of Their Structural, Optical, and Magnetic Properties