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

Katea, Sarmad Naim; Broqvist, Peter; Kullgren, Jolla; Hemmer, Eva; Westin, Gunnar

doi:10.1021/acs.inorgchem.0c00472

“…A short review focused on the synthesis and connected properties is given in the in ref. (48) besides general reviews on Ln-doped ZnO and their properties and more comprehensive reviews are found in (45,47).…”

Section: Introductionmentioning

confidence: 99%

“…DFT modelling, using dimeric Eu 3+ ion pairs flanking a metal vacancy for charge neutrality placed in the ZnO structure, did not result in any significant reduction of the unit cellvolume, compared to a linear Vegard type model using the calculated ionic radius of 83.5 pm for four coordinated Eu 3+ ions. (48) This indicates that while it might seem possible for the flanking Eu 3+ ions to make use of the Zn 2+ -ion vacancy void between two Eu 3+ ions, the surrounding ZnO lattice would be compressed around the site, resulting in increased ZnO cell-parameters resulting in a small energy gain compared to larger clusters. Thus, while it was shown that the Eu 3+ ions resided within the ZnO crystals, without a clearly visible phase separation in TEM imaging or XRD analysis, their local dopant structure remained unknown.…”

Section: Introductionmentioning

confidence: 99%

Molecular sized Eu-oxide clusters in defining optical properties in crystalline ZnO nanosponges

Mukherjee

¹

,

Katea

²

,

Rodrigues

³

et al. 2021

Preprint

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The detailed structure of ZnO doped with 5 at.% (metal) of the large aliovalent Eu3+-ions was investigated using EXAFS to describe the local Eu and Zn coordination. The microstructure, crystalline phases, contents and ZnO unit-cell parameters for the ZnO:5%Eu sponges synthesised at 200 to 900 oC were obtained by XRD, SEM, and TEM analysis. XRD showed peaks solely of h-ZnO for the 600 oC sample, while heating at 700 oC and higher caused phase separation into h-ZnO:Eu and c-Eu2O3. XRD showed a close to zero increase in ZnO unit cell-volume of ca. 0.4 vol%, compared to un-doped ZnO for the non-phase separated, clean oxide made at 600 oC. The Zn EXAFS data showed an almost intact local ZnO structure. The Eu EXAFS showed an unusually low coordination number (CN) of ca. 5 for the 200-600 oC samples, while the CN increased for higher temperatures, in concert with the formation of c-Eu2O3. 23 DFT-generated theoretical ZnO structures containing Eu-clusters built from 1 to 4 Eu3+-Zn2+-vacancy- Eu3+ pairs were compared with the experimental data. The lowest formation energies and ZnO unit-cell volume increase versus un-doped ZnO (0.6-0.7 vol%), were obtained when combining two or four Eu3+-Zn2+-vacancy- Eu3+ pairs into Eu4 and Eu8 clusters showing an average Eu CN of ca. 5. These theoretically determined lowest energy structures were all in good agreement with the experimental results obtained by EXAFS and XRD. Photoluminescence excitation and emission spectra performed on the ZnO:5at%Eu sponges obtained at various temperatures, showed strong quenching of the characteristic Eu3+ transitions for samples obtained at 600 and 800 °C, most likely due to changes in the ZnO defect states, which are crucial for Eu3+ excitation, and due to self-quenching upon Eu clustering and c- Eu2O3 phase separation. Thus, the optical data further supported Eu clustering found by EXAFS, DFT and XRD techniques, corroborating structure-property relationships in these materials. Overall, as far as we can find, the findings reported herein point to a doping structure very different from those previously proposed in the literature. It demonstrates that the semiconductor ZnO can host molecular-sized clusters of metal-oxides, very dissimilar to ZnO.

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“…Therefore, there has been an ongoing discussion on the reality and nature of such Eu-doped ZnO, not the least due the close to zero changes in XRD unit cell-dimensions observed with high levels of Eu 3+ doping. A short review focused on the synthesis and connected properties is given in the in ref.(48) besides general reviews on Ln-doped ZnO and their properties and more comprehensive reviews are found in (45,47).It has recently been proven beyond doubt, that the Eu 3+ ions are situated within the ZnO nanocrystals when using synthesis temperatures from 200 to 700 o C. (48,49) In these studies, TG analysis, XRD, XPS, IR spectroscopy, SEM, TEM-ED/EDS, STEM-EELS mapping, and optical measurements were used to describe the chemistry and structure of Eu doped ZnO. It was found that at 200 to 500 o C, there were also minor amounts of organic residues or carbonate present, besides the Eu 3+ ions.…”

mentioning

confidence: 99%

“…This allows to understand the unexpected doping structure and how the ZnO unit cell-dimensions can be retained on doping with high levels of large, alio-valent ions such as Eu 3+ .Furthermore, the changes in coordination over the temperature range, 200 to 900 o C, were examined to follow the Eu-dopant coordination; from the lowest synthesis temperature of 200 o C, to the clean, Eu-doped oxide obtained at 600 o C, and further into the temperature range, 700-900 o C, where the Eu is expelled from the ZnO to yield 5-10 nm sized c-Eu2O3 particles on the ZnO sponge surface.The Eu-doped ZnO microstructures were also further described with SEM and TEM imaging, although more thorough microscopy studies, including TEM-EELS mapping has been provided elsewhere. (48,49) The optical studies provided insight into the energy levels and properties of the minor defects in these materials, not accessible by the TEM and EXAFS probes.Based on the results obtained in this study, highly complex and to-date unforeseen molecularlike dopant structures are proposed that may shed light on various hard to explain magnetic and optical data for this kind of semi-conductor materials. The findings reported herein also point to a general possibility to form clusters of "misfit"-ions within rigid semi-conductor structures for the design of optical, magnetic, catalytic and transport properties, where typically a high dopant level is desired, while the semi-conductor properties are sensitive to disturbances in the semi-conductor lattice.…”

mentioning

confidence: 99%

“…It has recently been proven beyond doubt, that the Eu 3+ ions are situated within the ZnO nanocrystals when using synthesis temperatures from 200 to 700 o C. (48,49) In these studies, TG analysis, XRD, XPS, IR spectroscopy, SEM, TEM-ED/EDS, STEM-EELS mapping, and optical measurements were used to describe the chemistry and structure of Eu doped ZnO. It was found that at 200 to 500 o C, there were also minor amounts of organic residues or carbonate present, besides the Eu 3+ ions.…”

mentioning

confidence: 99%

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Molecular sized Eu-oxide clusters in defining optical properties in crystalline ZnO nanosponges

Mukherjee

¹

,

Katea

²

,

Rodrigues

³

et al. 2021

Preprint

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0

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The detailed structure of ZnO doped with 5 at.% (metal) of the large aliovalent Eu3+-ions was investigated using EXAFS to describe the local Eu and Zn coordination. The microstructure, crystalline phases, contents and ZnO unit-cell parameters for the ZnO:5%Eu sponges synthesised at 200 to 900 oC were obtained by XRD, SEM, and TEM analysis. XRD showed peaks solely of h-ZnO for the 600 oC sample, while heating at 700 oC and higher caused phase separation into h-ZnO:Eu and c-Eu2O3. XRD showed a close to zero increase in ZnO unit cell-volume of ca. 0.4 vol%, compared to un-doped ZnO for the non-phase separated, clean oxide made at 600 oC. The Zn EXAFS data showed an almost intact local ZnO structure. The Eu EXAFS showed an unusually low coordination number (CN) of ca. 5 for the 200-600 oC samples, while the CN increased for higher temperatures, in concert with the formation of c-Eu2O3. 23 DFT-generated theoretical ZnO structures containing Eu-clusters built from 1 to 4 Eu3+-Zn2+-vacancy- Eu3+ pairs were compared with the experimental data. The lowest formation energies and ZnO unit-cell volume increase versus un-doped ZnO (0.6-0.7 vol%), were obtained when combining two or four Eu3+-Zn2+-vacancy- Eu3+ pairs into Eu4 and Eu8 clusters showing an average Eu CN of ca. 5. These theoretically determined lowest energy structures were all in good agreement with the experimental results obtained by EXAFS and XRD. Photoluminescence excitation and emission spectra performed on the ZnO:5at%Eu sponges obtained at various temperatures, showed strong quenching of the characteristic Eu3+ transitions for samples obtained at 600 and 800 °C, most likely due to changes in the ZnO defect states, which are crucial for Eu3+ excitation, and due to self-quenching upon Eu clustering and c- Eu2O3 phase separation. Thus, the optical data further supported Eu clustering found by EXAFS, DFT and XRD techniques, corroborating structure-property relationships in these materials. Overall, as far as we can find, the findings reported herein point to a doping structure very different from those previously proposed in the literature. It demonstrates that the semiconductor ZnO can host molecular-sized clusters of metal-oxides, very dissimilar to ZnO.

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Entrapped Molecule‐Like Europium‐Oxide Clusters in Zinc Oxide with Nearly Unaffected Host Structure

Mukherjee

¹

,

Katea

²

,

Rodrigues

³

et al. 2022

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Nanocrystalline ZnO sponges doped with 5 mol% EuO1.5 are obtained by heating metal–salt complex based precursor pastes at 200–900 °C for 3 min. X‐ray diffraction, transmission electron microscopy, and extended X‐ray absorption fine structure (EXAFS) show that phase separation into ZnO:Eu and c‐Eu2O3 takes place upon heating at 700 °C or higher. The unit cell of the clean oxide made at 600 °C shows only ≈0.4% volume increase versus undoped ZnO, and EXAFS shows a ZnO local structure that is little affected by the Eu‐doping and an average Eu3+ ion coordination number of ≈5.2. Comparisons of 23 density functional theory‐generated structures having differently sized Eu‐oxide clusters embedded in ZnO identify three structures with four or eight Eu atoms as the most energetically favorable. These clusters exhibit the smallest volume increase compared to undoped ZnO and Eu coordination numbers of 5.2–5.5, all in excellent agreement with experimental data. ZnO defect states are crucial for efficient Eu3+ excitation, while c‐Eu2O3 phase separation results in loss of the characteristic Eu3+ photoluminescence. The formation of molecule‐like Eu‐oxide clusters, entrapped in ZnO, proposed here, may help in understanding the nature of the unexpected high doping levels of lanthanide ions in ZnO that occur virtually without significant change in ZnO unit cell dimensions.

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

Cited by 18 publications

References 137 publications

Molecular sized Eu-oxide clusters in defining optical properties in crystalline ZnO nanosponges

Molecular sized Eu-oxide clusters in defining optical properties in crystalline ZnO nanosponges

Molecular sized Eu-oxide clusters in defining optical properties in crystalline ZnO nanosponges

Entrapped Molecule‐Like Europium‐Oxide Clusters in Zinc Oxide with Nearly Unaffected Host Structure

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