Podlogar, Matejka

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Author's Bibliography

Effect of the sintering technique on the properties of Sb-doped BaSnO3 ceramics

Vukašinović, Jelena; Počuča-Nešić, Milica; Malešević, Aleksandar; Ribić, Vesna; Drev, Sandra; Rečnik, Aleksander; Bernik, Slavko; Podlogar, Matejka; Branković, Goran

(University of Belgrade, Institute for Multidisciplinary Research, 2022) 

TY  - CONF
AU  - Vukašinović, Jelena
AU  - Počuča-Nešić, Milica
AU  - Malešević, Aleksandar
AU  - Ribić, Vesna
AU  - Drev, Sandra
AU  - Rečnik, Aleksander
AU  - Bernik, Slavko
AU  - Podlogar, Matejka
AU  - Branković, Goran
PY  - 2022
UR  - http://rimsi.imsi.bg.ac.rs/handle/123456789/2026
AB  - Barium stannate, BaSnO3 (BSO), a cubic perovskite-type oxide with its
interesting structural, optical and electrical properties has wide application as an
electrode material, thermally stable capacitor, transparent conductive oxide,
photocatalyst, humidity and gas sensor material [1]. Partial substitution of Sn by Sb
in BSO leads to drastic changes primarily in its electrical properties, resulting in
metallic-like conductivity of doped ceramics. Major problems concerning the
synthesis of Sb doped BSO (BSSO) are connected to the phase composition and
density of final ceramic material.
This study covers the comprehensive investigation of structural, microstructural
and electrical properties of the Sb-doped BaSn1-xSbxO3 (x = 0.00, 0.04 and 0.08,
BSSO) ceramic materials obtained by two different sintering techniques:
conventional sintering (CS) and Spark Plasma sintering (SPS). The relative densities
of the BSSO-CS ceramic samples sintered at 1600 °C for 3 h was in the range of 79–
96 %. On the other side, the relative densities of BSSO-SPS ceramic samples in the
range of 86–96 % were obtained at 1200 °C, with sintering time of only 5 minutes.
The XRD analysis confirmed that cubic BaSnO3 is a major phase in all BSSO
samples. The presence of tetragonal Ba2SnO4 as a secondary phase was detected in
BSSO-SPS ceramic samples, with its content decreasing upon Sb-doping. As
expected, the grain size of the samples sintered at higher temperatures (BSSO-CS) is
larger in comparison with BSSO-SPS ceramic samples, which was confirmed by
Scanning Electron Microscopy (SEM). SEM analysis also revealed the layered
structure within the grains of BaSn0.92Sb0.08O3-CS sample while HRTEM analysis
confirmed the existence of the low angle grain boundaries (LAGBs) in the SPSed
sample with the same composition.
The electrical resistivity decreased upon Sb doping, and all doped BSSO
samples showed the linear I-U characteristic in the temperature range of 25–150 °C.
The semiconductor behavior of all BSSO-CS and BSSO-SPS (x = 0.00 and 0.04)
ceramic samples was confirmed through the existence of semicircles in their
impedance spectra. On the other hand, the BaSn0.92Sb0.08O3 sample showed the
metallic-like behavior resulting from the loss of the electrostatic barriers at LAGBs,
which is manifested through the absence of the semicircle in its impedance spectra.
PB  - University of Belgrade, Institute for Multidisciplinary Research
C3  - 6th Conference of the Serbian Society for Ceramic Materials, 6CSCS-2022, June 28-29, 2022, Belgrade, Serbia
T1  - Effect of the sintering technique on the properties of Sb-doped BaSnO3 ceramics
UR  - https://hdl.handle.net/21.15107/rcub_rimsi_2026
ER  - 
@conference{
author = "Vukašinović, Jelena and Počuča-Nešić, Milica and Malešević, Aleksandar and Ribić, Vesna and Drev, Sandra and Rečnik, Aleksander and Bernik, Slavko and Podlogar, Matejka and Branković, Goran",
year = "2022",
abstract = "Barium stannate, BaSnO3 (BSO), a cubic perovskite-type oxide with its
interesting structural, optical and electrical properties has wide application as an
electrode material, thermally stable capacitor, transparent conductive oxide,
photocatalyst, humidity and gas sensor material [1]. Partial substitution of Sn by Sb
in BSO leads to drastic changes primarily in its electrical properties, resulting in
metallic-like conductivity of doped ceramics. Major problems concerning the
synthesis of Sb doped BSO (BSSO) are connected to the phase composition and
density of final ceramic material.
This study covers the comprehensive investigation of structural, microstructural
and electrical properties of the Sb-doped BaSn1-xSbxO3 (x = 0.00, 0.04 and 0.08,
BSSO) ceramic materials obtained by two different sintering techniques:
conventional sintering (CS) and Spark Plasma sintering (SPS). The relative densities
of the BSSO-CS ceramic samples sintered at 1600 °C for 3 h was in the range of 79–
96 %. On the other side, the relative densities of BSSO-SPS ceramic samples in the
range of 86–96 % were obtained at 1200 °C, with sintering time of only 5 minutes.
The XRD analysis confirmed that cubic BaSnO3 is a major phase in all BSSO
samples. The presence of tetragonal Ba2SnO4 as a secondary phase was detected in
BSSO-SPS ceramic samples, with its content decreasing upon Sb-doping. As
expected, the grain size of the samples sintered at higher temperatures (BSSO-CS) is
larger in comparison with BSSO-SPS ceramic samples, which was confirmed by
Scanning Electron Microscopy (SEM). SEM analysis also revealed the layered
structure within the grains of BaSn0.92Sb0.08O3-CS sample while HRTEM analysis
confirmed the existence of the low angle grain boundaries (LAGBs) in the SPSed
sample with the same composition.
The electrical resistivity decreased upon Sb doping, and all doped BSSO
samples showed the linear I-U characteristic in the temperature range of 25–150 °C.
The semiconductor behavior of all BSSO-CS and BSSO-SPS (x = 0.00 and 0.04)
ceramic samples was confirmed through the existence of semicircles in their
impedance spectra. On the other hand, the BaSn0.92Sb0.08O3 sample showed the
metallic-like behavior resulting from the loss of the electrostatic barriers at LAGBs,
which is manifested through the absence of the semicircle in its impedance spectra.",
publisher = "University of Belgrade, Institute for Multidisciplinary Research",
journal = "6th Conference of the Serbian Society for Ceramic Materials, 6CSCS-2022, June 28-29, 2022, Belgrade, Serbia",
title = "Effect of the sintering technique on the properties of Sb-doped BaSnO3 ceramics",
url = "https://hdl.handle.net/21.15107/rcub_rimsi_2026"
}
Vukašinović, J., Počuča-Nešić, M., Malešević, A., Ribić, V., Drev, S., Rečnik, A., Bernik, S., Podlogar, M.,& Branković, G.. (2022). Effect of the sintering technique on the properties of Sb-doped BaSnO3 ceramics. in 6th Conference of the Serbian Society for Ceramic Materials, 6CSCS-2022, June 28-29, 2022, Belgrade, Serbia
University of Belgrade, Institute for Multidisciplinary Research..
https://hdl.handle.net/21.15107/rcub_rimsi_2026
Vukašinović J, Počuča-Nešić M, Malešević A, Ribić V, Drev S, Rečnik A, Bernik S, Podlogar M, Branković G. Effect of the sintering technique on the properties of Sb-doped BaSnO3 ceramics. in 6th Conference of the Serbian Society for Ceramic Materials, 6CSCS-2022, June 28-29, 2022, Belgrade, Serbia. 2022;.
https://hdl.handle.net/21.15107/rcub_rimsi_2026 .
Vukašinović, Jelena, Počuča-Nešić, Milica, Malešević, Aleksandar, Ribić, Vesna, Drev, Sandra, Rečnik, Aleksander, Bernik, Slavko, Podlogar, Matejka, Branković, Goran, "Effect of the sintering technique on the properties of Sb-doped BaSnO3 ceramics" in 6th Conference of the Serbian Society for Ceramic Materials, 6CSCS-2022, June 28-29, 2022, Belgrade, Serbia (2022),
https://hdl.handle.net/21.15107/rcub_rimsi_2026 .

TEM study of basal-plane inversion boundaries in Sn‐Doped ZnO

Ribić, Vesna; Rečnik, Aleksander; Dražić, Goran; Komelj, Matej; kokalj, Anton; Podlogar, Matejka; Daneu, Nina; Bernik, Slavko; Radošević, Tina; Luković Golić, Danijela; Branković, Zorica; Branković, Goran

(Ruđer Bošković Institute and Croatian Microscopy Society, Rovinj (Croatia), 2017) 

TY  - CONF
AU  - Ribić, Vesna
AU  - Rečnik, Aleksander
AU  - Dražić, Goran
AU  - Komelj, Matej
AU  - kokalj, Anton
AU  - Podlogar, Matejka
AU  - Daneu, Nina
AU  - Bernik, Slavko
AU  - Radošević, Tina
AU  - Luković Golić, Danijela
AU  - Branković, Zorica
AU  - Branković, Goran
PY  - 2017
UR  - http://rimsi.imsi.bg.ac.rs/handle/123456789/2463
AB  - Various dopants are known to produce inversion boundaries (IBs) in ZnO, causing polarity inversion across the interface. These are found either in basal or pyramidal planes and can be of head-to-head or tail-to-tail configuration with respect to the orientation of the polar c-axis. The dopants, known to produce IBs in ZnO are: In2O3, Fe2O3, Mn2O3, Ga2O3, SiO2, SnO2, TiO2 and Sb2O3. While some of IBs have been studied in detail, many IB structures remain unresolved. In our study we investigated structure and chemistry of basal plane inversion boundaries in SnO2-doped ZnO. The formation of IBs in this system was first reported by Daneu et al. (2000)1 and using high-resolution transmission electron microscopy the same group attempted to solve structure and chemistry of Sn-rich IBs.2 Implementing an innovative analytical approach based on acquiring multiple EDS spectra with concentric electron probes they showed that Sn4+ ions do not occupy the full IB layer, but rather one half of the layer. This suggested an average oxidation state of III+ for the cations comprising the IB plane. Based on electron micro-diffraction and HRTEM study Daneu et al.1,2 reported that Sn-rich IBs are head-to-head oriented with interfacial cations located in trigonal prismatic sites, however, the exact atomic arrangement of Sn along IB has not been determined. To identify the translation state and atomic arrangement on Sn-rich IBs in ZnO we performed quantitative HRTEM and HAADF-STEM analysis of SnO2-doped ZnO/Bi2O3 ceramics. IBs in ZnO grains were observed for two low-index orientations, [100] and [120], to obtain a 3D information on the translation state of the IB plane. The coordination site of interfacial cations was shown to be octahedral.
472
Translation obtained from images is compared with three different, so far known, types of the head-to-head IB translations with octahedral coordination of cations at IB-plane: (i) IB with stacking of the cation sublattice, as observed with Sb doping, (ii) IB with, as observed with In and Fe doping and (iii) IB with as observed with Mn doping. For Sn-doped ZnO translations turned out to be (ii) , the same as the one occurring in In- and Fe-doped ZnO. Based on experimental observations of local atomic arrangement, HRTEM and HAADF-STEM image simulations were performed for two different in-plane distributions of Sn and Zn atoms, to better understand experimental image contrast on IBs. The generated models will be further used for ab-initio calculations aimed at determining the electronic structure of IBs.
PB  - Ruđer Bošković Institute and Croatian Microscopy Society, Rovinj (Croatia)
C3  - 13th Multinational Congress on Microscopy, Rovinj, Croatia, 2017
T1  - TEM study of basal-plane inversion boundaries in Sn‐Doped ZnO
SP  - 471
UR  - https://hdl.handle.net/21.15107/rcub_rimsi_2463
ER  - 
@conference{
author = "Ribić, Vesna and Rečnik, Aleksander and Dražić, Goran and Komelj, Matej and kokalj, Anton and Podlogar, Matejka and Daneu, Nina and Bernik, Slavko and Radošević, Tina and Luković Golić, Danijela and Branković, Zorica and Branković, Goran",
year = "2017",
abstract = "Various dopants are known to produce inversion boundaries (IBs) in ZnO, causing polarity inversion across the interface. These are found either in basal or pyramidal planes and can be of head-to-head or tail-to-tail configuration with respect to the orientation of the polar c-axis. The dopants, known to produce IBs in ZnO are: In2O3, Fe2O3, Mn2O3, Ga2O3, SiO2, SnO2, TiO2 and Sb2O3. While some of IBs have been studied in detail, many IB structures remain unresolved. In our study we investigated structure and chemistry of basal plane inversion boundaries in SnO2-doped ZnO. The formation of IBs in this system was first reported by Daneu et al. (2000)1 and using high-resolution transmission electron microscopy the same group attempted to solve structure and chemistry of Sn-rich IBs.2 Implementing an innovative analytical approach based on acquiring multiple EDS spectra with concentric electron probes they showed that Sn4+ ions do not occupy the full IB layer, but rather one half of the layer. This suggested an average oxidation state of III+ for the cations comprising the IB plane. Based on electron micro-diffraction and HRTEM study Daneu et al.1,2 reported that Sn-rich IBs are head-to-head oriented with interfacial cations located in trigonal prismatic sites, however, the exact atomic arrangement of Sn along IB has not been determined. To identify the translation state and atomic arrangement on Sn-rich IBs in ZnO we performed quantitative HRTEM and HAADF-STEM analysis of SnO2-doped ZnO/Bi2O3 ceramics. IBs in ZnO grains were observed for two low-index orientations, [100] and [120], to obtain a 3D information on the translation state of the IB plane. The coordination site of interfacial cations was shown to be octahedral.
472
Translation obtained from images is compared with three different, so far known, types of the head-to-head IB translations with octahedral coordination of cations at IB-plane: (i) IB with stacking of the cation sublattice, as observed with Sb doping, (ii) IB with, as observed with In and Fe doping and (iii) IB with as observed with Mn doping. For Sn-doped ZnO translations turned out to be (ii) , the same as the one occurring in In- and Fe-doped ZnO. Based on experimental observations of local atomic arrangement, HRTEM and HAADF-STEM image simulations were performed for two different in-plane distributions of Sn and Zn atoms, to better understand experimental image contrast on IBs. The generated models will be further used for ab-initio calculations aimed at determining the electronic structure of IBs.",
publisher = "Ruđer Bošković Institute and Croatian Microscopy Society, Rovinj (Croatia)",
journal = "13th Multinational Congress on Microscopy, Rovinj, Croatia, 2017",
title = "TEM study of basal-plane inversion boundaries in Sn‐Doped ZnO",
pages = "471",
url = "https://hdl.handle.net/21.15107/rcub_rimsi_2463"
}
Ribić, V., Rečnik, A., Dražić, G., Komelj, M., kokalj, A., Podlogar, M., Daneu, N., Bernik, S., Radošević, T., Luković Golić, D., Branković, Z.,& Branković, G.. (2017). TEM study of basal-plane inversion boundaries in Sn‐Doped ZnO. in 13th Multinational Congress on Microscopy, Rovinj, Croatia, 2017
Ruđer Bošković Institute and Croatian Microscopy Society, Rovinj (Croatia)., 471.
https://hdl.handle.net/21.15107/rcub_rimsi_2463
Ribić V, Rečnik A, Dražić G, Komelj M, kokalj A, Podlogar M, Daneu N, Bernik S, Radošević T, Luković Golić D, Branković Z, Branković G. TEM study of basal-plane inversion boundaries in Sn‐Doped ZnO. in 13th Multinational Congress on Microscopy, Rovinj, Croatia, 2017. 2017;:471.
https://hdl.handle.net/21.15107/rcub_rimsi_2463 .
Ribić, Vesna, Rečnik, Aleksander, Dražić, Goran, Komelj, Matej, kokalj, Anton, Podlogar, Matejka, Daneu, Nina, Bernik, Slavko, Radošević, Tina, Luković Golić, Danijela, Branković, Zorica, Branković, Goran, "TEM study of basal-plane inversion boundaries in Sn‐Doped ZnO" in 13th Multinational Congress on Microscopy, Rovinj, Croatia, 2017 (2017):471,
https://hdl.handle.net/21.15107/rcub_rimsi_2463 .