Bright Red Luminescence and Structural Properties of Eu&amp;lt;sup&amp;gt;3+&amp;lt;/sup&amp;gt; Ion Doped ZnO by Solution Combustion Technique

López-Romero, S.; Quiroz-Jiménez, M. J.; García, Manuel Hipólito; Aguilar-Castillo, A.

doi:10.4236/wjcmp.2014.44024

Cited by 17 publications

(11 citation statements)

References 29 publications

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“…The latter shoulder peak is broad and might be composed of several components in spite of the very good fit when using one peak component. This peak is sometimes also connected to defects, such as oxygen vacancies, showing a peak appearing in the lower-BE part of this oxygen peak. ,,,,,,,,− ,,− It might also contain a component of carboxylate or carbonate oxygen with a slightly higher BE of 531.6 eV, found for the Eu–oxo-carbonate, as indicated by its IR spectrum . Yet, a minor component of it could fit within the high-BE side of the broad 531.33 eV peak.…”

Section: Resultsmentioning

confidence: 97%

“…In the Eu 3d region, the ZnO:5%Eu sample showed two sets of peaks around 1134 and 1164 eV, corresponding to photoemission from the Eu 3d 5/2 and Eu 3d 3/2 levels, respectively. ,− ,,,,,,,,,,,− The Eu 3d 5/2 core level peaks can be seen as consisting of three groups with peak components at (i) 1124.30 (1.62) and 1126.44 (1.37), (ii) 1131.66 sh (6.38), 1134.34 (76.99), and 1136.84 sh (8.87), and (iii) 1142.87 (4.77) eV. Following the prevailing assignments in the literature, the first group of peak components on the low-energy side are associated with Eu 2+ , while the second group of peaks are associated with Eu 3+ . ,,, These BE values correspond well with the literature values for europium oxides. ,,,,,,,,− ,,− , The satellite peak at 1142.87 eV is associated with shake-down processes. , …”

Section: Resultsmentioning

confidence: 98%

“…Regarding Eu-doped ZnO, there is a large variety of structures reported, including thin films, rods/wires, sea urchins, cauliflower-like balls, and powders, achieved by a wide range of chemical and physical synthesis routes, including radio frequency sputtering, − pulsed laser deposition, ion implantion, , chemical vapor deposition, vapor transport deposition, ,− spray pyrolysis, , solid-state synthesis, ,, electrochemical synthesis, − combustion synthesis, − precipitation and hydro-/solvothermal synthesis, − hydrothermal microemulsion processing, sonochemically assisted precipitation, chemical solution deposition, − and metal–organic decomposition . A more detailed review of the results given in these references is provided in Review S1.…”

Section: Introductionmentioning

confidence: 99%

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Fast, Low-Cost Synthesis of ZnO:Eu Nanosponges and the Nature of Ln Doping in ZnO

et al. 2020

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A low-cost template-free solution chemical route to highly porous nanocrystalline sponges of ZnO-EuO 1.5 with 0−5 mol % Eu is presented. The process uses Zn− and Eu−acetate− nitrate and triethanolamine as precursors in methanol. After evaporation of the solvent and heating at 200 °C for 3 min, crystalline ZnO:Eu sponges with minor amounts of organic residues were obtained. Heating to 400 °C replaced the organics with carbonate, which in its turn was decomposed at temperatures below 600 °C, forming ZnO:Eu sponges. Samples heated to 200− 1000 °C for 3 min were studied with XRD, SEM, TEM, TG, XPS, and IR spectroscopy. The ZnO:Eu crystallite sizes could be tuned from below 10 nm for sponges prepared at 200−500 °C, to over 100 nm range at 900 °C, without sintering of the overall microstructure. XRD showed the presence of hexagonal ZnO:Eu (or at 700−1000 °C, ZnO:Eu and cubic Eu 2 O 3 ) as the only phases present. The ZnO:Eu had slightly larger unit cell dimensions than the literature value of ZnO for samples obtained at 200−600 °C, while the unit cells of samples obtained at higher temperatures were quite close to the value of undoped ZnO. XPS showed that Eu was mainly in its 3+ state and well-distributed within the sponges but segregated at the ZnO sponge surface upon heating at 700− 1000 °C, in accordance with XRD studies showing Eu 2 O 3 formation.

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Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Fast, Low-Cost Synthesis of ZnO:Eu Nanosponges and the Nature of Ln Doping in ZnO

et al. 2020

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“…The Figure 4(a) and Figure 4(b) shows the room temperature photoluminescence spectra (PL) of the Eu 3+ doped ZnO without the Cu 2+ ion dopant and of the Cu 2+ +Eu 3+ doped ZnO (ZnO:Cu 2+ +Eu 3+ ) nanocrystals as a function of the Cu 2+ ion concentration in Wt% and after both samples undoped and doped with the Cu 2+ were annealing at 900˚C by 24 h, the samples were irradiated with an excitation wavelength of 270 nm (in the UV range). In Figure 4(a) it is observed that the PL spectra correspond to the Eu 3+ ion emission in a ZnO matrix, in particular the most intense peak at the visible color red whit 613 nm in wavelength [27]. However it is observed from Figure 4(b) that the ZnO:Cu 2+ +Eu 3+ samples doped with 1, 2, 3, 10, and 20 Wt% are all alike: because they does not present antypical green broad emission band from 400 nm to 600 nm centered about 516 nm [28] as is showed in Figure 4(a), this band is due to the intrinsic defects emission of ZnO host.…”

Section: Photoluminescence Studymentioning

confidence: 98%

“…The introduction of Cu 2+ ions into ZnO lattice sums or produces changes that improve the ZnO properties such as: band gap tailored, magnetic and electrical properties, passivation of defects, as p-type dopant in the original n-type ZnO semiconductor. However, actually it is well known that the co-doping with Cu 2+ ion in Eu 3+ doped glasses photoluminescent compounds the Cu 2+ ion can quench the Eu 3+ photoluminescence [27]- [29] with the increase of the Cu 2+ ion concentration in glasses matrix; this quenching effect can be used to tuning between ultra-violet and visible emission in devise photoluminescent. In this study co-doped ZnO/Cu 2+ + Eu 3+ solid solution powders have been synthesized by solution combustion method as a function of the Cu 2+ ion concentration in %Wt.…”

Section: Introductionmentioning

confidence: 99%

Quenching Photoluminescence of Eu(III) by Cu(II) in ZnO:Eu3++Cu2+ Compounds by Solution Combustion Method

López-Romero¹,

Jiménez²,

Garcı́a-Hipólito³

2016

WJCMP

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In this study Cu 2+ +Eu 3+ co-doped ZnO(ZnO/Cu 2+ +Eu 3+ ) solid solution powders were synthesized by solution combustion method using as oxidant agent zinc nitrate hexahydrate and as fuel urea; the Cu 2+ concentrations were 0, 1, 2, 3, 10, and 20 %Wt; the Eu 3+ ion concentration was fixed in 3%Wt. The samples after were annealed at 900˚C by 20 h in air. The structural results showed the largely presence of a wurtzite solid solution of Cu 2+ +Eu 3+ doped ZnO, at high Cu 2+ doping CuO and Eu 2 CuO 4 phases are also present. Morphological properties were analyzed using scanning electron microscopy (SEM) technique. However it is important to remark that the Cu 2+ ions suppress the Eu 3+ ion photoluminescence (PL) by means of an overlap mechanism between Cu 2+ absorption band and Eu 3+ emission band (e.g. 5 D 0 → 7 F 2 ) of the Eu 3+ emission spectra.

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Effect of Eu Doping on the Physical, Photoluminescence, and Photocatalytic Characteristics of ZnO Thin Films Grown by Sol–Gel Method

Rayes

Kumar

Cortés-Jácome

et al. 2017

Physica Status Solidi (a)

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Eu doping concentration driven effect on the morphological, electrical, and optical properties of ZnO films prepared by sol gel method have been studied systematically. The properties of the films were studied using various experimental tools such as XRD, AFM, XPS, photoconductivity, UV–vis spectroscopy, photoluminescence (PL), and photocatalytic activity. Eu incorporation into the ZnO lattice was confirmed by XPS analysis. A decrease in crystallite size with increasing Eu concentration was observed. PL spectra showed that Eu‐ related light emission intensity reached a maximum at 6 wt.%. Photoconductivity measurements showed maximum photosensitivity for 4 wt.% Eu doped film. The photocatalytic activity of Eu‐ doped films was evaluated for methylene blue degradation and is found to be maximum for 6 wt.% Eu doped film.

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Bright Red Luminescence and Structural Properties of Eu<sup>3+</sup> Ion Doped ZnO by Solution Combustion Technique

Cited by 17 publications

References 29 publications

Fast, Low-Cost Synthesis of ZnO:Eu Nanosponges and the Nature of Ln Doping in ZnO

Fast, Low-Cost Synthesis of ZnO:Eu Nanosponges and the Nature of Ln Doping in ZnO

Quenching Photoluminescence of Eu(III) by Cu(II) in ZnO:Eu3++Cu2+ Compounds by Solution Combustion Method

Effect of Eu Doping on the Physical, Photoluminescence, and Photocatalytic Characteristics of ZnO Thin Films Grown by Sol–Gel Method

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