TY  - JOUR
AU  - Tančić, Pavle
AU  - Milošević, Maja
AU  - Spahić, Darko
AU  - Kostić, Bojan
AU  - Kremenović, Aleksandar
AU  - Poznanović-Spahić, Maja
AU  - Kovačević, Jovan
PY  - 2024
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/7538
AB  - Five celestine crystals are sampled from the (paleo)surface intervening between the late Miocene to Pleistocene basaltic sequences of the Jabal Eghei(Nuqay) volcanic province (southern Libya). The celestine specimens are characterized by applying the combination of the SEM-WDS, ICP/OES, XRPD, and IR methods. The celestine minerals are further analyzed for their color variations and minerogenetic framework. Three samples have greenish-blue-to-blue (480.4-482.5 nm), whereas the other two samples have blue-green color (cyan; 489.1-494.1 nm). The color purity ranges from 1.36-7.16. Their similarity of chemical content is fitting into the celestine near-end members, in which exclusively 1.6-4.1 at. % of Sr2+ content was substituted by Pb2+ (0.7-0.9 at. %), Ba2+ (0.5-0.7 at. %) and Ca2+ (0.2-0.8 at. %). The composition includes vacancies ranging from 1.0 to 1.9 at. % (observed only in three samples). The content of other chemical elements is minor. The resulting unit-cell parameters have the following ranges: a0=8.3578(9)-8.3705(6) Å; b0=5.3510(5)-5.3568(4) Å; c0=6.8683(7)-6.8767(2) Å and V0=307.17(5)-308.34(4) Å3. The XRPD and IR results are mainly in accordance with the SEM-WDS results, having a higher level of correlativity. However, the analysis exposed a few discrepancies yielding several possible interpretations. The illustrated discrepancies were primarily caused by a slight unit-cell axial anisotropy i.e., thermal expansion. In this manner, the results yield a new geothermometric tool that is based on the unit-cell axial anisotropy. The investigated Sr-bearing celestines were formed during a Miocene intraplate volcanism, basaltic magmas, and associated brines lifted by the structural conduits (normal faults crosscutting the Sirt basin). The Sr-bearing fluids were then poured into and over the faulted and fractured lagoon-type gypsum, anhydrite Eocene sediments. The celestine minerals were produced within a ~ 368-430K (~ 95-157 oC) temperature range. The celestine is formed at slightly elevated temperature and pressure conditions, close to the shallow subsurface environment (over 250 bars).
PB  - Cambridge University Press
T2  - Mineralogical Magazine
T1  - Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer
VL  - 88
IS  - 1
SP  - 1
EP  - 18
DO  - 10.1180/mgm.2023.88
ER  - 

@article{
author = "Tančić, Pavle and Milošević, Maja and Spahić, Darko and Kostić, Bojan and Kremenović, Aleksandar and Poznanović-Spahić, Maja and Kovačević, Jovan",
year = "2024",
abstract = "Five celestine crystals are sampled from the (paleo)surface intervening between the late Miocene to Pleistocene basaltic sequences of the Jabal Eghei(Nuqay) volcanic province (southern Libya). The celestine specimens are characterized by applying the combination of the SEM-WDS, ICP/OES, XRPD, and IR methods. The celestine minerals are further analyzed for their color variations and minerogenetic framework. Three samples have greenish-blue-to-blue (480.4-482.5 nm), whereas the other two samples have blue-green color (cyan; 489.1-494.1 nm). The color purity ranges from 1.36-7.16. Their similarity of chemical content is fitting into the celestine near-end members, in which exclusively 1.6-4.1 at. % of Sr2+ content was substituted by Pb2+ (0.7-0.9 at. %), Ba2+ (0.5-0.7 at. %) and Ca2+ (0.2-0.8 at. %). The composition includes vacancies ranging from 1.0 to 1.9 at. % (observed only in three samples). The content of other chemical elements is minor. The resulting unit-cell parameters have the following ranges: a0=8.3578(9)-8.3705(6) Å; b0=5.3510(5)-5.3568(4) Å; c0=6.8683(7)-6.8767(2) Å and V0=307.17(5)-308.34(4) Å3. The XRPD and IR results are mainly in accordance with the SEM-WDS results, having a higher level of correlativity. However, the analysis exposed a few discrepancies yielding several possible interpretations. The illustrated discrepancies were primarily caused by a slight unit-cell axial anisotropy i.e., thermal expansion. In this manner, the results yield a new geothermometric tool that is based on the unit-cell axial anisotropy. The investigated Sr-bearing celestines were formed during a Miocene intraplate volcanism, basaltic magmas, and associated brines lifted by the structural conduits (normal faults crosscutting the Sirt basin). The Sr-bearing fluids were then poured into and over the faulted and fractured lagoon-type gypsum, anhydrite Eocene sediments. The celestine minerals were produced within a ~ 368-430K (~ 95-157 oC) temperature range. The celestine is formed at slightly elevated temperature and pressure conditions, close to the shallow subsurface environment (over 250 bars).",
publisher = "Cambridge University Press",
journal = "Mineralogical Magazine",
title = "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer",
volume = "88",
number = "1",
pages = "1-18",
doi = "10.1180/mgm.2023.88"
}

Tančić, P., Milošević, M., Spahić, D., Kostić, B., Kremenović, A., Poznanović-Spahić, M.,& Kovačević, J.. (2024). Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer. in Mineralogical Magazine
Cambridge University Press., 88(1), 1-18.
https://doi.org/10.1180/mgm.2023.88

Tančić P, Milošević M, Spahić D, Kostić B, Kremenović A, Poznanović-Spahić M, Kovačević J. Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer. in Mineralogical Magazine. 2024;88(1):1-18.
doi:10.1180/mgm.2023.88 .

Tančić, Pavle, Milošević, Maja, Spahić, Darko, Kostić, Bojan, Kremenović, Aleksandar, Poznanović-Spahić, Maja, Kovačević, Jovan, "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer" in Mineralogical Magazine, 88, no. 1 (2024):1-18,
https://doi.org/10.1180/mgm.2023.88 . .

TY  - JOUR
AU  - Tančić, Pavle
AU  - Milošević, Maja
AU  - Spahić, Darko
AU  - Kostić, Bojan
AU  - Kremenović, Aleksandar
AU  - Poznanović-Spahić, Maja
AU  - Kovačević, Jovan
PY  - 2024
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/7539
AB  - An error was introduced during production in the section of text on p. 10 under the heading “(v)
The option that various structural variations within the samples could take place”, in paragraph
six.
The published text reads:
“For possibility (b), the major celestines with the disregarded gypsum or anhydrite phases, the
results in Supplementary Tables S10 and S16 demonstrate that there is a slightly different ratio
between various crystallographic axes, such as c0 < a0 <b0 (samples 1 and 4), a0 < c0 <b0
(samples 2 and 3) and a0 = c0 < b0 (sample 5).”
The text ‘possibility (b)’ should be changed to ‘possibility 2’, and hence the descriptor ‘the major
celestines with the disregarded gypsum or anhydrite phases’ should be removed.
The correct text is:
“For possibility (2), the results in Supplementary Tables S10 and S16 demonstrate that there is a
slightly different ratio between various crystallographic axes, such as c0 < a0 <b0 (samples 1 and
4), a0 < c0 <b0 (samples 2 and 3) and a0 = c0 < b0 (sample 5).”
PB  - Cambridge University Press
T2  - Mineralogical Magazine
T1  - Characterisation, axial anisotropy, and formation conditions of celestine minerals from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southeastern edge of the Sirt Basin, southern Libya: Constraints on the mineralogical geothermometer – ERRATUM
SP  - 1
EP  - 1
DO  - 10.1180/mgm.2024.12
ER  - 

@article{
author = "Tančić, Pavle and Milošević, Maja and Spahić, Darko and Kostić, Bojan and Kremenović, Aleksandar and Poznanović-Spahić, Maja and Kovačević, Jovan",
year = "2024",
abstract = "An error was introduced during production in the section of text on p. 10 under the heading “(v)
The option that various structural variations within the samples could take place”, in paragraph
six.
The published text reads:
“For possibility (b), the major celestines with the disregarded gypsum or anhydrite phases, the
results in Supplementary Tables S10 and S16 demonstrate that there is a slightly different ratio
between various crystallographic axes, such as c0 < a0 <b0 (samples 1 and 4), a0 < c0 <b0
(samples 2 and 3) and a0 = c0 < b0 (sample 5).”
The text ‘possibility (b)’ should be changed to ‘possibility 2’, and hence the descriptor ‘the major
celestines with the disregarded gypsum or anhydrite phases’ should be removed.
The correct text is:
“For possibility (2), the results in Supplementary Tables S10 and S16 demonstrate that there is a
slightly different ratio between various crystallographic axes, such as c0 < a0 <b0 (samples 1 and
4), a0 < c0 <b0 (samples 2 and 3) and a0 = c0 < b0 (sample 5).”",
publisher = "Cambridge University Press",
journal = "Mineralogical Magazine",
title = "Characterisation, axial anisotropy, and formation conditions of celestine minerals from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southeastern edge of the Sirt Basin, southern Libya: Constraints on the mineralogical geothermometer – ERRATUM",
pages = "1-1",
doi = "10.1180/mgm.2024.12"
}

Tančić, P., Milošević, M., Spahić, D., Kostić, B., Kremenović, A., Poznanović-Spahić, M.,& Kovačević, J.. (2024). Characterisation, axial anisotropy, and formation conditions of celestine minerals from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southeastern edge of the Sirt Basin, southern Libya: Constraints on the mineralogical geothermometer – ERRATUM. in Mineralogical Magazine
Cambridge University Press., 1-1.
https://doi.org/10.1180/mgm.2024.12

Tančić P, Milošević M, Spahić D, Kostić B, Kremenović A, Poznanović-Spahić M, Kovačević J. Characterisation, axial anisotropy, and formation conditions of celestine minerals from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southeastern edge of the Sirt Basin, southern Libya: Constraints on the mineralogical geothermometer – ERRATUM. in Mineralogical Magazine. 2024;:1-1.
doi:10.1180/mgm.2024.12 .

Tančić, Pavle, Milošević, Maja, Spahić, Darko, Kostić, Bojan, Kremenović, Aleksandar, Poznanović-Spahić, Maja, Kovačević, Jovan, "Characterisation, axial anisotropy, and formation conditions of celestine minerals from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southeastern edge of the Sirt Basin, southern Libya: Constraints on the mineralogical geothermometer – ERRATUM" in Mineralogical Magazine (2024):1-1,
https://doi.org/10.1180/mgm.2024.12 . .

TY  - JOUR
AU  - Tančić, Pavle
AU  - Milošević, Maja
AU  - Spahić, Darko
AU  - Kostić, Bojan
AU  - Kremenović, Aleksandar
AU  - Poznanović-Spahić, Maja
AU  - Kovačević, Jovan
PY  - 2024
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6913
AB  - Five celestine crystals are sampled from the (paleo)surface intervening between the late Miocene to Pleistocene basaltic sequences of the Jabal Eghei(Nuqay) volcanic province (southern Libya). The celestine specimens are characterized by applying the combination of the SEM-WDS, ICP/OES, XRPD, and IR methods. The celestine minerals are further analyzed for their color variations and minerogenetic framework. Three samples have greenish-blue-to-blue (480.4-482.5 nm), whereas the other two samples have blue-green color (cyan; 489.1-494.1 nm). The color purity ranges from 1.36-7.16. Their similarity of chemical content is fitting into the celestine near-end members, in which exclusively 1.6-4.1 at. % of Sr2+ content was substituted by Pb2+ (0.7-0.9 at. %), Ba2+ (0.5-0.7 at. %) and Ca2+ (0.2-0.8 at. %). The composition includes vacancies ranging from 1.0 to 1.9 at. % (observed only in three samples). The content of other chemical elements is minor. The resulting unit-cell parameters have the following ranges: a0=8.3578(9)-8.3705(6) Å; b0=5.3510(5)-5.3568(4) Å; c0=6.8683(7)-6.8767(2) Å and V0=307.17(5)-308.34(4) Å3. The XRPD and IR results are mainly in accordance with the SEM-WDS results, having a higher level of correlativity. However, the analysis exposed a few discrepancies yielding several possible interpretations. The illustrated discrepancies were primarily caused by a slight unit-cell axial anisotropy i.e., thermal expansion. In this manner, the results yield a new geothermometric tool that is based on the unit-cell axial anisotropy. The investigated Sr-bearing celestines were formed during a Miocene intraplate volcanism, basaltic magmas, and associated brines lifted by the structural conduits (normal faults crosscutting the Sirt basin). The Sr-bearing fluids were then poured into and over the faulted and fractured lagoon-type gypsum, anhydrite Eocene sediments. The celestine minerals were produced within a ~ 368-430K (~ 95-157 oC) temperature range. The celestine is formed at slightly elevated temperature and pressure conditions, close to the shallow subsurface environment (over 250 bars).
PB  - Cambridge University Press
T2  - Mineralogical Magazine
T1  - Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer
VL  - 88
IS  - 1
SP  - 1
EP  - 18
DO  - 10.1180/mgm.2023.88
ER  - 

@article{
author = "Tančić, Pavle and Milošević, Maja and Spahić, Darko and Kostić, Bojan and Kremenović, Aleksandar and Poznanović-Spahić, Maja and Kovačević, Jovan",
year = "2024",
abstract = "Five celestine crystals are sampled from the (paleo)surface intervening between the late Miocene to Pleistocene basaltic sequences of the Jabal Eghei(Nuqay) volcanic province (southern Libya). The celestine specimens are characterized by applying the combination of the SEM-WDS, ICP/OES, XRPD, and IR methods. The celestine minerals are further analyzed for their color variations and minerogenetic framework. Three samples have greenish-blue-to-blue (480.4-482.5 nm), whereas the other two samples have blue-green color (cyan; 489.1-494.1 nm). The color purity ranges from 1.36-7.16. Their similarity of chemical content is fitting into the celestine near-end members, in which exclusively 1.6-4.1 at. % of Sr2+ content was substituted by Pb2+ (0.7-0.9 at. %), Ba2+ (0.5-0.7 at. %) and Ca2+ (0.2-0.8 at. %). The composition includes vacancies ranging from 1.0 to 1.9 at. % (observed only in three samples). The content of other chemical elements is minor. The resulting unit-cell parameters have the following ranges: a0=8.3578(9)-8.3705(6) Å; b0=5.3510(5)-5.3568(4) Å; c0=6.8683(7)-6.8767(2) Å and V0=307.17(5)-308.34(4) Å3. The XRPD and IR results are mainly in accordance with the SEM-WDS results, having a higher level of correlativity. However, the analysis exposed a few discrepancies yielding several possible interpretations. The illustrated discrepancies were primarily caused by a slight unit-cell axial anisotropy i.e., thermal expansion. In this manner, the results yield a new geothermometric tool that is based on the unit-cell axial anisotropy. The investigated Sr-bearing celestines were formed during a Miocene intraplate volcanism, basaltic magmas, and associated brines lifted by the structural conduits (normal faults crosscutting the Sirt basin). The Sr-bearing fluids were then poured into and over the faulted and fractured lagoon-type gypsum, anhydrite Eocene sediments. The celestine minerals were produced within a ~ 368-430K (~ 95-157 oC) temperature range. The celestine is formed at slightly elevated temperature and pressure conditions, close to the shallow subsurface environment (over 250 bars).",
publisher = "Cambridge University Press",
journal = "Mineralogical Magazine",
title = "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer",
volume = "88",
number = "1",
pages = "1-18",
doi = "10.1180/mgm.2023.88"
}

Tančić, P., Milošević, M., Spahić, D., Kostić, B., Kremenović, A., Poznanović-Spahić, M.,& Kovačević, J.. (2024). Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer. in Mineralogical Magazine
Cambridge University Press., 88(1), 1-18.
https://doi.org/10.1180/mgm.2023.88

Tančić P, Milošević M, Spahić D, Kostić B, Kremenović A, Poznanović-Spahić M, Kovačević J. Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer. in Mineralogical Magazine. 2024;88(1):1-18.
doi:10.1180/mgm.2023.88 .

Tančić, Pavle, Milošević, Maja, Spahić, Darko, Kostić, Bojan, Kremenović, Aleksandar, Poznanović-Spahić, Maja, Kovačević, Jovan, "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer" in Mineralogical Magazine, 88, no. 1 (2024):1-18,
https://doi.org/10.1180/mgm.2023.88 . .

TY  - DATA
AU  - Tančić, Pavle
AU  - Milošević, Maja
AU  - Spahić, Darko
AU  - Kostić, Bojan
AU  - Kremenović, Aleksandar
AU  - Poznanović-Spahić, Maja
AU  - Kovačević, Jovan
PY  - 2023
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/7147
AB  - Figure S1. a The investigated area within the circum-Mediterranean realm; b Geological Mapping campaign of central and southern Libya (marked with green color); c The wider area of the Al Haruj and Jabal Eghei Volcanic Provinces; d Jabal Eghei Volcanic Province; and e The surface-exposed basalts as the result of the three Middle Miocene to Pliocene volcanic events (according to Radivojević et al. 2015). The spots of the celestine sampling locations are marked with the “×” symbol, collected from the area of the sheet NF 34-1, Geological Map of Libya, scale 1:250,000 (marked with red color).
Figure S2. SEM photos (column I, left) and sum spectrums (column II, right) of the analyzed 1-5 samples. 
Figure S3. The observed (column I, left) XRPD patterns of the 1-5 samples. The Le Bail (1988) profile fitting (column II, right) of the XRPD patterns of the 1-5 samples. The observed spectra (red dotted line), fitted spectra (black solid line), difference plot (blue solid line) and Bragg peak positions (green tick marks), are shown as well. 
Table S1. Observed interplanar spacings (dobs, in Å) and relative intensity ratios-RIR (Iobs, in %) of the studied samples; compared to the reference ICDD-PDF's (ICDD-PDF: International Centre for Diffraction Data-Powder Diffraction File) 89-0953 and 05-0593 data standards. 
Figure S4. Comparative presentation of the reflections with following Miller's hkl indices: (a) 002; (b) 210; (c) 102; (d) 211; (e) 112 (left) and 020 (right); (f) 122 & 113 (left) and 203 & 401 (right); (g) 004; (h) 323; (i) 040 (left) and 431 (right); and (j) 006. 
Figure S5. Magnified 24.5-30.5o (column I, left) and 31-90o (column II, right) 2θ angle ranges of the Le Bail (1988) profile fittings (Figure S3, column II). 
Table S2. Selected profile parameters and reliability factors refined from the Le Bail (1988) profile fitting method. 
Figure S6. Linear (column I, left) and polynomial [column II, right; C(1)] variations for 1-5 samples of: (a & d) axis a0 (in Å) by axis c0 (in Å); (b & e) axis a0 (in Å) by volume V0 (in Å3); and (c & f) axis c0 (in Å) by volume V0 (in Å3). Marks “+” denote celestine positions (ICDD-PDF: 89-0953). 
Figure S7. Linear (column I, left) and polynomial [column II, right; C(2)] variations of the axis b0 (in Å) for 1-5 samples by: (a & d) axis a0 (in Å); (b & e) axis c0 (in Å); and (c & f) volume V0 (in Å3). Marks “+” denote celestine positions (ICDD-PDF: 89-0953). 
Figure S8. Positions of the polynomial variations of the studied samples (Figures S6 and S7) in regard to the celestine, anglesite and barite standards [ICDD-PDF's: 89-0953 (marked as “+”), 36-1461 (marked as “☼”) and 24-1035 (marked as “×”), respectively]: (a) axis b0 (in Å) by axis a0 (in Å); (b) axis a0 (in Å) by axis c0 (in Å); (c) axis b0 (in Å) by axis c0 (in Å); (d) axis a0 (in Å) by volume V0 (in Å3); (e) axis b0 (in Å) by volume V0 (in Å3); and (f) axis c0 (in Å) by volume V0 (in Å3). Celestine-anglesite linear joins were marked with dotted lines, whereas celestine-barite linear joins were marked with interrupted lines.  
Table S3. Calculated differences (in %) between the UCPs for various solid-solutions series. 
Figure S9. Infrared spectra of the studied samples.
Figure S10. Chromatic diagram of the studied samples. 
Figure S11. Linear (column I, left) and polynomial [column II, right; C(3)] variations of the calculated ionic radiuses (in Å; Table 2) for 1-5 samples by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” and “×” denote celestine positions (ICDD-PDF's: 89-0953 and 05-0593, respectively). 
Table S4. Correlations of the different studied variations (see Discussion, for details).
Table S5. Determined apfu’s (in at. %) at the 2 (ΣM+S) ions basis from the determined WDS analyses (Table 1). 
Table S6. Calculated theoretical ionic radiuses (in Å) of the M cations, and calculated occupancies of the twelve-coordination site (in at. %) at basis of the determined apfu’s (Table S5). 
Figure S12. Linear (column I, left) and polynomial [column II, right; C(4)] variations of the calculated ionic radiuses (in Å; Table S6) for 1-5 samples by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S7. Recalculated (calc1-3) WDS analyses of the 1-5 studied samples (in wt. %). Atoms per formula units (apfu; in at. %) were calculated at 4 oxygen anions basis. 
Table S8. Recalculated (calc1-3) theoretical ionic radiuses (in Å) of the M cations, and calculated occupancies of the twelve-coordination site (in at. %) at basis of the recalculated (calc1-3) WDS analyses (Table S7). 
Figure S13. Linear (column I, left) and polynomial [column II, right; C(5)] variations of the calculated ionic radiuses (in Å) for 1-5 samples without calculated anhydrite or gypsum contents (Table S8; calc1,2) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” denote celestine positions (ICDD-PDF: 89-0953). 
Figure S14. Linear (column I, left) and polynomial [column II, right; C(6)] variations of the calculated ionic radiuses (in Å) for 1-5 samples without calculated anhydrite, gypsum and other minerals with the X component contents (Table S8; calc3) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” denote celestine positions (ICDD-PDF: 89-0953). 
Table S9. Recalculated theoretical ionic radiuses (in Å) of the M+S6+ ions and calculated occupancies of the twelve-coordination site within two possible options for celestines: as monomineral („mono“; Table 2), and without minor anhydrite („A“) or gypsum („G“) contents (Table S8; calc1,2). 
Figure S15. Linear (column I, left) and polynomial [column II, right; C(7)] variations of the recalculated ionic radiuses (in Å) for 1-5 samples treated as monomineral celestines (Table S9; „mono“) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” and “×” denote celestine positions (ICDD-PDF's: 89-0953 and 05-0593, respectively). 
Figure S16. Linear (column I, left) and polynomial [column II, right; C(8)] variations of the recalculated ionic radiuses (in Å) for 1-5 samples treated as major celestines with neglected anhydrite („A“) or gypsum („G“) contents (Table S9) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” and “×” denote celestine positions (ICDD-PDF's: 89-0953 and 05-0593, respectively). 
Table S10. Determined (marked as „det“; Table 5) and presumed (marked as „pre“) UCPs of the studied samples (as monomineral, Table 1); and without minor anhydrite („A“) and gypsum („G“) contents (Table S7). Differences (Δ) and ratios between these are also presented. 
Figure S17. Linear (column I, left) and polynomial [column II, right; C(9)] variations of the calculated ionic radiuses (in Å; Table 2) for monomineral 1-5 samples (Table S10) by: (a & e) ratio of axis a0; (b & f) ratio of axis b0; (c & g) ratio of axis c0; and (d & h) ratio of volume V0. 
Figure S18. Linear (column I, left) and polynomial [column II, right; C(10)] variations of the calculated ionic radiuses (in Å; Table S8) for 1-5 samples without calculated Ca from anhydrite or gypsum contents (Table S10) by: (a & e) ratio of axis a0; (b & f) ratio of axis b0; (c & g) ratio of axis c0; and (d & h) ratio of volume V0. 
Figure S19. Linear (column I, left) and polynomial [column II, right; C(11)] variations of the presumed (Table S10) by determined (Table 5) UCPs: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S11. UCPs and average <M-O> distances (in Å) of the selected celestines. 
Table S12. Recalculated apfu’s (in at. %) from Table 1. 
Table S13. Recalculated theoretical ionic radiuses (in Å) of the M cations, and occupancies of the twelve-coordination site (in at. %) from Table 2. 
Table S14. Recalculated apfu’s (in at. %) from Table S7 (calc1,2). 
Table S15. Recalculated theoretical ionic radiuses (in Å) of the M cations, and occupancies of the twelve-coordination site (in at. %) from Table S8.
Figure S20. Linear (column I, left) and polynomial [column II, right; C(12)] variations of the recalculated ionic radiuses (in Å) for 1-5 samples treated as monomineral celestines (Table S13) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Figure S21. Linear (column I, left) and polynomial [column II, right; C(13)] variations of the recalculated ionic radiuses (in Å) for 1-5 samples treated as major celestines with neglected anhydrite or gypsum contents (Table S15) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S16. Determined (marked as „obs“; Table 5) and presumed (marked as „calc“) UCPs of the studied samples as monomineral celestines (Table S12). Differences (Δ) and ratios between these are also presented. 
Figure S22. Linear (column I, left) and polynomial [column II, right; C(14)] variations of the calculated (Table S16; marked as „calc“) by observed (Table 5; marked as „obs“) UCPs: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S17. Recalculated variations of temperature dependence by UCPs for the Clt98Ang02, Clt96Ang04 and Clt94Ang06 celestine-anglesite solid-solution series, at the ambient pressure conditions. 
Table S18. Recalculated variations of temperature dependence by UCPs for the Clt99Brt01, Clt98Brt02 and Clt97Brt03 celestine-barite solid-solution series, at the ambient pressure conditions. 
Table S19. Relative UCPs of celestine, anglesite and barite, calculated from the ratio of the data at 320K* and 520K (Tables S17 and S18). 
Figure S23. Five possible different variations (plotted from Figure 3h) of: 1. volume increase by a temperature increase, including the Brt contents increase; 2. volume increase by a constant temperature, including the Brt contents increase; 3. volume increase by a temperature decrease, including the Brt contents increase; 4. constant volume by a temperature increase, including the Brt contents decrease; and 5. volume increase by a temperature increase, having a constant Brt content. 
Figure S24. Linear (column I, left) and polynomial [column II, right; C(15)] variations of the temperature (in K) for 1-5 samples (Tables 5 and 8) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S20. Estimated UCPs of the studied samples at room temperature (23 oC) and ambient pressure conditions, at basis of the extrapolated data presented in Tables S17 and S18; Table 8 and Figure 3. 
Figure S25. Linear (column I, left) and polynomial [column II, right; C(16)] variations of the average temperature (in K) for 1-5 samples (Table 8) by ratio (Table 9) of: (a & e) axis a0; (b & f) axis b0; (c & g) axis c0; and (d & h) volume V0.
PB  - Cambridge University Press
T1  - Supplementary Materials for: "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer"
UR  - https://hdl.handle.net/21.15107/rcub_cer_7147
ER  - 

@misc{
author = "Tančić, Pavle and Milošević, Maja and Spahić, Darko and Kostić, Bojan and Kremenović, Aleksandar and Poznanović-Spahić, Maja and Kovačević, Jovan",
year = "2023",
abstract = "Figure S1. a The investigated area within the circum-Mediterranean realm; b Geological Mapping campaign of central and southern Libya (marked with green color); c The wider area of the Al Haruj and Jabal Eghei Volcanic Provinces; d Jabal Eghei Volcanic Province; and e The surface-exposed basalts as the result of the three Middle Miocene to Pliocene volcanic events (according to Radivojević et al. 2015). The spots of the celestine sampling locations are marked with the “×” symbol, collected from the area of the sheet NF 34-1, Geological Map of Libya, scale 1:250,000 (marked with red color).
Figure S2. SEM photos (column I, left) and sum spectrums (column II, right) of the analyzed 1-5 samples. 
Figure S3. The observed (column I, left) XRPD patterns of the 1-5 samples. The Le Bail (1988) profile fitting (column II, right) of the XRPD patterns of the 1-5 samples. The observed spectra (red dotted line), fitted spectra (black solid line), difference plot (blue solid line) and Bragg peak positions (green tick marks), are shown as well. 
Table S1. Observed interplanar spacings (dobs, in Å) and relative intensity ratios-RIR (Iobs, in %) of the studied samples; compared to the reference ICDD-PDF's (ICDD-PDF: International Centre for Diffraction Data-Powder Diffraction File) 89-0953 and 05-0593 data standards. 
Figure S4. Comparative presentation of the reflections with following Miller's hkl indices: (a) 002; (b) 210; (c) 102; (d) 211; (e) 112 (left) and 020 (right); (f) 122 & 113 (left) and 203 & 401 (right); (g) 004; (h) 323; (i) 040 (left) and 431 (right); and (j) 006. 
Figure S5. Magnified 24.5-30.5o (column I, left) and 31-90o (column II, right) 2θ angle ranges of the Le Bail (1988) profile fittings (Figure S3, column II). 
Table S2. Selected profile parameters and reliability factors refined from the Le Bail (1988) profile fitting method. 
Figure S6. Linear (column I, left) and polynomial [column II, right; C(1)] variations for 1-5 samples of: (a & d) axis a0 (in Å) by axis c0 (in Å); (b & e) axis a0 (in Å) by volume V0 (in Å3); and (c & f) axis c0 (in Å) by volume V0 (in Å3). Marks “+” denote celestine positions (ICDD-PDF: 89-0953). 
Figure S7. Linear (column I, left) and polynomial [column II, right; C(2)] variations of the axis b0 (in Å) for 1-5 samples by: (a & d) axis a0 (in Å); (b & e) axis c0 (in Å); and (c & f) volume V0 (in Å3). Marks “+” denote celestine positions (ICDD-PDF: 89-0953). 
Figure S8. Positions of the polynomial variations of the studied samples (Figures S6 and S7) in regard to the celestine, anglesite and barite standards [ICDD-PDF's: 89-0953 (marked as “+”), 36-1461 (marked as “☼”) and 24-1035 (marked as “×”), respectively]: (a) axis b0 (in Å) by axis a0 (in Å); (b) axis a0 (in Å) by axis c0 (in Å); (c) axis b0 (in Å) by axis c0 (in Å); (d) axis a0 (in Å) by volume V0 (in Å3); (e) axis b0 (in Å) by volume V0 (in Å3); and (f) axis c0 (in Å) by volume V0 (in Å3). Celestine-anglesite linear joins were marked with dotted lines, whereas celestine-barite linear joins were marked with interrupted lines.  
Table S3. Calculated differences (in %) between the UCPs for various solid-solutions series. 
Figure S9. Infrared spectra of the studied samples.
Figure S10. Chromatic diagram of the studied samples. 
Figure S11. Linear (column I, left) and polynomial [column II, right; C(3)] variations of the calculated ionic radiuses (in Å; Table 2) for 1-5 samples by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” and “×” denote celestine positions (ICDD-PDF's: 89-0953 and 05-0593, respectively). 
Table S4. Correlations of the different studied variations (see Discussion, for details).
Table S5. Determined apfu’s (in at. %) at the 2 (ΣM+S) ions basis from the determined WDS analyses (Table 1). 
Table S6. Calculated theoretical ionic radiuses (in Å) of the M cations, and calculated occupancies of the twelve-coordination site (in at. %) at basis of the determined apfu’s (Table S5). 
Figure S12. Linear (column I, left) and polynomial [column II, right; C(4)] variations of the calculated ionic radiuses (in Å; Table S6) for 1-5 samples by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S7. Recalculated (calc1-3) WDS analyses of the 1-5 studied samples (in wt. %). Atoms per formula units (apfu; in at. %) were calculated at 4 oxygen anions basis. 
Table S8. Recalculated (calc1-3) theoretical ionic radiuses (in Å) of the M cations, and calculated occupancies of the twelve-coordination site (in at. %) at basis of the recalculated (calc1-3) WDS analyses (Table S7). 
Figure S13. Linear (column I, left) and polynomial [column II, right; C(5)] variations of the calculated ionic radiuses (in Å) for 1-5 samples without calculated anhydrite or gypsum contents (Table S8; calc1,2) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” denote celestine positions (ICDD-PDF: 89-0953). 
Figure S14. Linear (column I, left) and polynomial [column II, right; C(6)] variations of the calculated ionic radiuses (in Å) for 1-5 samples without calculated anhydrite, gypsum and other minerals with the X component contents (Table S8; calc3) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” denote celestine positions (ICDD-PDF: 89-0953). 
Table S9. Recalculated theoretical ionic radiuses (in Å) of the M+S6+ ions and calculated occupancies of the twelve-coordination site within two possible options for celestines: as monomineral („mono“; Table 2), and without minor anhydrite („A“) or gypsum („G“) contents (Table S8; calc1,2). 
Figure S15. Linear (column I, left) and polynomial [column II, right; C(7)] variations of the recalculated ionic radiuses (in Å) for 1-5 samples treated as monomineral celestines (Table S9; „mono“) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” and “×” denote celestine positions (ICDD-PDF's: 89-0953 and 05-0593, respectively). 
Figure S16. Linear (column I, left) and polynomial [column II, right; C(8)] variations of the recalculated ionic radiuses (in Å) for 1-5 samples treated as major celestines with neglected anhydrite („A“) or gypsum („G“) contents (Table S9) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). Marks “+” and “×” denote celestine positions (ICDD-PDF's: 89-0953 and 05-0593, respectively). 
Table S10. Determined (marked as „det“; Table 5) and presumed (marked as „pre“) UCPs of the studied samples (as monomineral, Table 1); and without minor anhydrite („A“) and gypsum („G“) contents (Table S7). Differences (Δ) and ratios between these are also presented. 
Figure S17. Linear (column I, left) and polynomial [column II, right; C(9)] variations of the calculated ionic radiuses (in Å; Table 2) for monomineral 1-5 samples (Table S10) by: (a & e) ratio of axis a0; (b & f) ratio of axis b0; (c & g) ratio of axis c0; and (d & h) ratio of volume V0. 
Figure S18. Linear (column I, left) and polynomial [column II, right; C(10)] variations of the calculated ionic radiuses (in Å; Table S8) for 1-5 samples without calculated Ca from anhydrite or gypsum contents (Table S10) by: (a & e) ratio of axis a0; (b & f) ratio of axis b0; (c & g) ratio of axis c0; and (d & h) ratio of volume V0. 
Figure S19. Linear (column I, left) and polynomial [column II, right; C(11)] variations of the presumed (Table S10) by determined (Table 5) UCPs: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S11. UCPs and average <M-O> distances (in Å) of the selected celestines. 
Table S12. Recalculated apfu’s (in at. %) from Table 1. 
Table S13. Recalculated theoretical ionic radiuses (in Å) of the M cations, and occupancies of the twelve-coordination site (in at. %) from Table 2. 
Table S14. Recalculated apfu’s (in at. %) from Table S7 (calc1,2). 
Table S15. Recalculated theoretical ionic radiuses (in Å) of the M cations, and occupancies of the twelve-coordination site (in at. %) from Table S8.
Figure S20. Linear (column I, left) and polynomial [column II, right; C(12)] variations of the recalculated ionic radiuses (in Å) for 1-5 samples treated as monomineral celestines (Table S13) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Figure S21. Linear (column I, left) and polynomial [column II, right; C(13)] variations of the recalculated ionic radiuses (in Å) for 1-5 samples treated as major celestines with neglected anhydrite or gypsum contents (Table S15) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S16. Determined (marked as „obs“; Table 5) and presumed (marked as „calc“) UCPs of the studied samples as monomineral celestines (Table S12). Differences (Δ) and ratios between these are also presented. 
Figure S22. Linear (column I, left) and polynomial [column II, right; C(14)] variations of the calculated (Table S16; marked as „calc“) by observed (Table 5; marked as „obs“) UCPs: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S17. Recalculated variations of temperature dependence by UCPs for the Clt98Ang02, Clt96Ang04 and Clt94Ang06 celestine-anglesite solid-solution series, at the ambient pressure conditions. 
Table S18. Recalculated variations of temperature dependence by UCPs for the Clt99Brt01, Clt98Brt02 and Clt97Brt03 celestine-barite solid-solution series, at the ambient pressure conditions. 
Table S19. Relative UCPs of celestine, anglesite and barite, calculated from the ratio of the data at 320K* and 520K (Tables S17 and S18). 
Figure S23. Five possible different variations (plotted from Figure 3h) of: 1. volume increase by a temperature increase, including the Brt contents increase; 2. volume increase by a constant temperature, including the Brt contents increase; 3. volume increase by a temperature decrease, including the Brt contents increase; 4. constant volume by a temperature increase, including the Brt contents decrease; and 5. volume increase by a temperature increase, having a constant Brt content. 
Figure S24. Linear (column I, left) and polynomial [column II, right; C(15)] variations of the temperature (in K) for 1-5 samples (Tables 5 and 8) by: (a & e) axis a0 (in Å); (b & f) axis b0 (in Å); (c & g) axis c0 (in Å); and (d & h) volume V0 (in Å3). 
Table S20. Estimated UCPs of the studied samples at room temperature (23 oC) and ambient pressure conditions, at basis of the extrapolated data presented in Tables S17 and S18; Table 8 and Figure 3. 
Figure S25. Linear (column I, left) and polynomial [column II, right; C(16)] variations of the average temperature (in K) for 1-5 samples (Table 8) by ratio (Table 9) of: (a & e) axis a0; (b & f) axis b0; (c & g) axis c0; and (d & h) volume V0.",
publisher = "Cambridge University Press",
title = "Supplementary Materials for: "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer"",
url = "https://hdl.handle.net/21.15107/rcub_cer_7147"
}

Tančić, P., Milošević, M., Spahić, D., Kostić, B., Kremenović, A., Poznanović-Spahić, M.,& Kovačević, J.. (2023). Supplementary Materials for: "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer". 
Cambridge University Press..
https://hdl.handle.net/21.15107/rcub_cer_7147

Tančić P, Milošević M, Spahić D, Kostić B, Kremenović A, Poznanović-Spahić M, Kovačević J. Supplementary Materials for: "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer". 2023;.
https://hdl.handle.net/21.15107/rcub_cer_7147 .

Tančić, Pavle, Milošević, Maja, Spahić, Darko, Kostić, Bojan, Kremenović, Aleksandar, Poznanović-Spahić, Maja, Kovačević, Jovan, "Supplementary Materials for: "Characterization, axial anisotropy and formation conditions of celestine from the Jabal Eghei (Nuqay) late Neogene – Pleistocene volcanic province, southern Libya: Constraints on the mineralogical geothermometer"" (2023),
https://hdl.handle.net/21.15107/rcub_cer_7147 .

TY  - JOUR
AU  - Šuljagić, Marija
AU  - Petronijević, Ivan
AU  - Mirković, Miljana
AU  - Kremenović, Aleksandar
AU  - Džunuzović, Adis
AU  - Pavlović, Vladimir B.
AU  - Kalezić-Glišović, Aleksandra
AU  - Anđelković, Ljubica
PY  - 2023
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/5865
AB  - To investigate the influence of spinel structure and sintering temperature on the functional properties of BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1), NiFe2O4, ZnFe2O4, and Ni0.5Zn0.5Fe2O4 were in situ prepared by thermal decomposition onto BaTiO3 surface from acetylacetonate precursors. As-prepared powders were additionally sintered at 1150 °C and 1300 °C. X-ray powder diffraction (XRPD) and scanning electron microscopy (SEM) coupled with electron dispersive spectroscopy (EDS) were used for the detailed examination of phase composition and morphology. The magnetic, dielectric, and ferroelectric properties were investigated. The optimal phase composition in the BaTiO3/NiFe2O4 composite, sintered at 1150 °C, resulted in a wide frequency range stability. Additionally, particular phase composition indicates favorable properties such as low conductivity and ideal-like hysteresis loop behavior. The favorable properties of BaTiO3/NiFe2O4 make this particular composite an ideal material choice for further studies on applications of multi-ferroic devices.
PB  - MDPI
T2  - Inorganics
T1  - BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1) Composites Synthesized by Thermal Decomposition: Magnetic, Dielectric and Ferroelectric Properties
VL  - 11
IS  - 2
SP  - 51
DO  - 10.3390/inorganics11020051
ER  - 

@article{
author = "Šuljagić, Marija and Petronijević, Ivan and Mirković, Miljana and Kremenović, Aleksandar and Džunuzović, Adis and Pavlović, Vladimir B. and Kalezić-Glišović, Aleksandra and Anđelković, Ljubica",
year = "2023",
abstract = "To investigate the influence of spinel structure and sintering temperature on the functional properties of BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1), NiFe2O4, ZnFe2O4, and Ni0.5Zn0.5Fe2O4 were in situ prepared by thermal decomposition onto BaTiO3 surface from acetylacetonate precursors. As-prepared powders were additionally sintered at 1150 °C and 1300 °C. X-ray powder diffraction (XRPD) and scanning electron microscopy (SEM) coupled with electron dispersive spectroscopy (EDS) were used for the detailed examination of phase composition and morphology. The magnetic, dielectric, and ferroelectric properties were investigated. The optimal phase composition in the BaTiO3/NiFe2O4 composite, sintered at 1150 °C, resulted in a wide frequency range stability. Additionally, particular phase composition indicates favorable properties such as low conductivity and ideal-like hysteresis loop behavior. The favorable properties of BaTiO3/NiFe2O4 make this particular composite an ideal material choice for further studies on applications of multi-ferroic devices.",
publisher = "MDPI",
journal = "Inorganics",
title = "BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1) Composites Synthesized by Thermal Decomposition: Magnetic, Dielectric and Ferroelectric Properties",
volume = "11",
number = "2",
pages = "51",
doi = "10.3390/inorganics11020051"
}

Šuljagić, M., Petronijević, I., Mirković, M., Kremenović, A., Džunuzović, A., Pavlović, V. B., Kalezić-Glišović, A.,& Anđelković, L.. (2023). BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1) Composites Synthesized by Thermal Decomposition: Magnetic, Dielectric and Ferroelectric Properties. in Inorganics
MDPI., 11(2), 51.
https://doi.org/10.3390/inorganics11020051

Šuljagić M, Petronijević I, Mirković M, Kremenović A, Džunuzović A, Pavlović VB, Kalezić-Glišović A, Anđelković L. BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1) Composites Synthesized by Thermal Decomposition: Magnetic, Dielectric and Ferroelectric Properties. in Inorganics. 2023;11(2):51.
doi:10.3390/inorganics11020051 .

Šuljagić, Marija, Petronijević, Ivan, Mirković, Miljana, Kremenović, Aleksandar, Džunuzović, Adis, Pavlović, Vladimir B., Kalezić-Glišović, Aleksandra, Anđelković, Ljubica, "BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1) Composites Synthesized by Thermal Decomposition: Magnetic, Dielectric and Ferroelectric Properties" in Inorganics, 11, no. 2 (2023):51,
https://doi.org/10.3390/inorganics11020051 . .

TY  - CONF
AU  - Šuljagić, Marija
AU  - Petronijević, Ivan
AU  - Mirković, Miljana
AU  - Kremenović, Aleksandar
AU  - Džunuzović, Adis
AU  - Pavlović, Vladimir
AU  - Kalezić-Glišović, Aleksandra
AU  - Anđelković, Ljubica
PY  - 2023
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6328
AB  - In order to examine the influence of phase composition and sintering temperature on the functional properties of perovskite/spinel composites, BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1), NiFe2O4, ZnFe2O4, and Ni0.5Zn0.5Fe2O4 were in situ prepared by thermal decomposition onto BaTiO3 surface. Acetylacetonate complexes were used as the precursors. The obtained powders were compressed to pellets and sintered at 1150 °C and 1300 °C. X-ray powder diffraction (XRPD) and scanning electron microscopy (SEM) coupled with electron dispersive spectroscopy (EDS) were used for the comprehensive investigation of phase composition and morphology. The magnetic, dielectric, and ferroelectric properties were performed in detail. The optimal phase composition was found in the BaTiO3/NiFe2O4 composite sintered at 1150 °C, which resulted in a wide frequency range stability. Furthermore, particular phase composition led to suitable properties such as low conductivity and ideal-like hysteresis loop behavior [1]. These functional properties of BaTiO3/NiFe2O4 make this composite a “material of choice“ for further studies on applications of multiferroic devices.
AB  - U cilju ispitivanja uticaja faznog sastava i temperature sinterovanja na funkcionalna svojstva perovskit/spinel kompozita BaTiO3/NixZn1−xFe2O4 (x = 0, 0,5, 1), NiFe2O4, ZnFe2O4, i Ni0,5Zn0,5Fe2O4 pripremljeni su in situ metodom termalne dekompozicije. U sintezi su korišćeni acetilacetonatni kompleksi kao prekursori. Dobijeni prahovi su komprimovani u tablete i sinterovani na 1150 °C i 1300 °C. Za detaljno ispitivanje faznog sastava i morfologije sintetisanih kompozita korišćene su metode rendgenske difrakcije praha (XRPD) i skenirajuće elektronske mikroskopije (SEM) spregnute sa energetsko disperzivnom spektroskopijom (EDS). Ispitivana su i magnetna, dielektrična i feroelektrična svojstva sinterovanih kompozita. Ustanovljeno je da optimalni fazni sastav pronađen kod kompozita BaTiO3/NiFe2O4 sinterovanog na 1150 °C dovodi do stabilnosti u širokom opsegu frekvencija. Optimalni fazni sastav pomenutog kompozita povoljno je uticao na funkcionalna svojstva kao što su niska provodnost i feroelektrično ponašenje koje se ogleda u zadovoljavajućem izgledu histerezisa [1]. Ova svojstva nedvosmisleno ukazuju da je kompozit BaTiO3/NiFe2O4 odgovarajući izbor za dalja istraživanja posvećena primeni multiferoičnih materijala.
PB  - Belgrade, Serbia : Serbian Cristallographic Soceity / Beograd, Srbija : Srpsko kristalografsko društvo
C3  - 28th Conference of the Serbian Crystallographic Society - Abstracts, June 14–15th, 2023 Čačak, Serbia / XXVIII Konferencija Srpskog kristalografskog društva - Izvodi radova, Jun 14–15, 2023 Čačak, Srbija
T1  - BaTiO3/NixZn1-xFe2O4 (x =0, 0.5, 1) composites synthesized by thermal decomposition: The influence of phase composition and sintering temperature on their physical properties
T1  - Uticaj faznog sastava i temperature sinterovanja na fizička svojstva BaTiO3/NixZn1-xFe2O4 (x =0, 0.5, 1) kompozita sintetisanih metodom termalne dekompozicije
SP  - 36
EP  - 37
UR  - https://hdl.handle.net/21.15107/rcub_cer_6328
ER  - 

@conference{
author = "Šuljagić, Marija and Petronijević, Ivan and Mirković, Miljana and Kremenović, Aleksandar and Džunuzović, Adis and Pavlović, Vladimir and Kalezić-Glišović, Aleksandra and Anđelković, Ljubica",
year = "2023",
abstract = "In order to examine the influence of phase composition and sintering temperature on the functional properties of perovskite/spinel composites, BaTiO3/NixZn1−xFe2O4 (x = 0, 0.5, 1), NiFe2O4, ZnFe2O4, and Ni0.5Zn0.5Fe2O4 were in situ prepared by thermal decomposition onto BaTiO3 surface. Acetylacetonate complexes were used as the precursors. The obtained powders were compressed to pellets and sintered at 1150 °C and 1300 °C. X-ray powder diffraction (XRPD) and scanning electron microscopy (SEM) coupled with electron dispersive spectroscopy (EDS) were used for the comprehensive investigation of phase composition and morphology. The magnetic, dielectric, and ferroelectric properties were performed in detail. The optimal phase composition was found in the BaTiO3/NiFe2O4 composite sintered at 1150 °C, which resulted in a wide frequency range stability. Furthermore, particular phase composition led to suitable properties such as low conductivity and ideal-like hysteresis loop behavior [1]. These functional properties of BaTiO3/NiFe2O4 make this composite a “material of choice“ for further studies on applications of multiferroic devices., U cilju ispitivanja uticaja faznog sastava i temperature sinterovanja na funkcionalna svojstva perovskit/spinel kompozita BaTiO3/NixZn1−xFe2O4 (x = 0, 0,5, 1), NiFe2O4, ZnFe2O4, i Ni0,5Zn0,5Fe2O4 pripremljeni su in situ metodom termalne dekompozicije. U sintezi su korišćeni acetilacetonatni kompleksi kao prekursori. Dobijeni prahovi su komprimovani u tablete i sinterovani na 1150 °C i 1300 °C. Za detaljno ispitivanje faznog sastava i morfologije sintetisanih kompozita korišćene su metode rendgenske difrakcije praha (XRPD) i skenirajuće elektronske mikroskopije (SEM) spregnute sa energetsko disperzivnom spektroskopijom (EDS). Ispitivana su i magnetna, dielektrična i feroelektrična svojstva sinterovanih kompozita. Ustanovljeno je da optimalni fazni sastav pronađen kod kompozita BaTiO3/NiFe2O4 sinterovanog na 1150 °C dovodi do stabilnosti u širokom opsegu frekvencija. Optimalni fazni sastav pomenutog kompozita povoljno je uticao na funkcionalna svojstva kao što su niska provodnost i feroelektrično ponašenje koje se ogleda u zadovoljavajućem izgledu histerezisa [1]. Ova svojstva nedvosmisleno ukazuju da je kompozit BaTiO3/NiFe2O4 odgovarajući izbor za dalja istraživanja posvećena primeni multiferoičnih materijala.",
publisher = "Belgrade, Serbia : Serbian Cristallographic Soceity / Beograd, Srbija : Srpsko kristalografsko društvo",
journal = "28th Conference of the Serbian Crystallographic Society - Abstracts, June 14–15th, 2023 Čačak, Serbia / XXVIII Konferencija Srpskog kristalografskog društva - Izvodi radova, Jun 14–15, 2023 Čačak, Srbija",
title = "BaTiO3/NixZn1-xFe2O4 (x =0, 0.5, 1) composites synthesized by thermal decomposition: The influence of phase composition and sintering temperature on their physical properties, Uticaj faznog sastava i temperature sinterovanja na fizička svojstva BaTiO3/NixZn1-xFe2O4 (x =0, 0.5, 1) kompozita sintetisanih metodom termalne dekompozicije",
pages = "36-37",
url = "https://hdl.handle.net/21.15107/rcub_cer_6328"
}

Šuljagić, M., Petronijević, I., Mirković, M., Kremenović, A., Džunuzović, A., Pavlović, V., Kalezić-Glišović, A.,& Anđelković, L.. (2023). BaTiO3/NixZn1-xFe2O4 (x =0, 0.5, 1) composites synthesized by thermal decomposition: The influence of phase composition and sintering temperature on their physical properties. in 28th Conference of the Serbian Crystallographic Society - Abstracts, June 14–15th, 2023 Čačak, Serbia / XXVIII Konferencija Srpskog kristalografskog društva - Izvodi radova, Jun 14–15, 2023 Čačak, Srbija
Belgrade, Serbia : Serbian Cristallographic Soceity / Beograd, Srbija : Srpsko kristalografsko društvo., 36-37.
https://hdl.handle.net/21.15107/rcub_cer_6328

Šuljagić M, Petronijević I, Mirković M, Kremenović A, Džunuzović A, Pavlović V, Kalezić-Glišović A, Anđelković L. BaTiO3/NixZn1-xFe2O4 (x =0, 0.5, 1) composites synthesized by thermal decomposition: The influence of phase composition and sintering temperature on their physical properties. in 28th Conference of the Serbian Crystallographic Society - Abstracts, June 14–15th, 2023 Čačak, Serbia / XXVIII Konferencija Srpskog kristalografskog društva - Izvodi radova, Jun 14–15, 2023 Čačak, Srbija. 2023;:36-37.
https://hdl.handle.net/21.15107/rcub_cer_6328 .

Šuljagić, Marija, Petronijević, Ivan, Mirković, Miljana, Kremenović, Aleksandar, Džunuzović, Adis, Pavlović, Vladimir, Kalezić-Glišović, Aleksandra, Anđelković, Ljubica, "BaTiO3/NixZn1-xFe2O4 (x =0, 0.5, 1) composites synthesized by thermal decomposition: The influence of phase composition and sintering temperature on their physical properties" in 28th Conference of the Serbian Crystallographic Society - Abstracts, June 14–15th, 2023 Čačak, Serbia / XXVIII Konferencija Srpskog kristalografskog društva - Izvodi radova, Jun 14–15, 2023 Čačak, Srbija (2023):36-37,
https://hdl.handle.net/21.15107/rcub_cer_6328 .

TY  - JOUR
AU  - Šuljagić, Marija
AU  - Kremenović, Aleksandar
AU  - Petronijević, Ivan
AU  - Džunuzović, Adis
AU  - Mirković, Miljana
AU  - Pavlović, Vladimir
AU  - Anđelković, Ljubica
PY  - 2023
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6643
AB  - To investigate the effect of synthesis procedure and sintering temperature on the functional properties of perovskite/spinel ceramics, BaTiO3/CoFe2O4 composites were prepared by thermal decomposition, coprecipitation, and microemulsion method, and sintered at 1150°C and 1300°C. The phase composition and morphology of as-prepared powders as well as sintered ceramics were thoroughly examined by X-ray powder diffraction (XRPD) and scanning electron microscopy (SEM) coupled with electron dispersive spectroscopy (EDS). The dielectric and ferroelectric measurements were performed in detail. Generally, the samples sintered at 1300°C had better performances than those sintered at 1150°C. The composite synthesized by thermal decomposition and sintered at 1300 °C stands out among other prepared BaTiO3/CoFe2O4 ceramics, owing to high stability in the wide frequency range and low leakage currents. The obtained results indicate that such composite might be successfully applied as a functional multiferroic.
AB  - У циљу испитивања утицаја методе синтезе као и температуре синтеровања на функционална својства керамике перовскитно/спинелне структуре, синтетисани су BaTiO3/CoFe2O4 композити методама термалне декомпозиције, копреципитације и микроемулзије, а затим синтеровани на 1150 °C и 1300 °C. Фазни састав и морфологија синтетисаних узорака детаљно су испитани пре и после синтеровања помоћу рендгенске дифракције на праху (XRPD) и скенирајуће електронске микроскпије (SEM) спрегнуте са елекрон дисперзивном спектроскопијом (EDS). Изведена су опсежна испитивања како диелектричних, тако и фероелектричних својстава датих композита. У већини случајева узорци синтеровани на 1300 °C показали су боља својства од узорака синтерованих на 1150 °C. Композит синтетисан методом термалне декомпозиције и синтерован на 1300 °C издваја се од осталих синтетисаних BaTiO3/CoFe2O4 узорака захваљујући великој стабилносту у широком фреквентном опсегу и малим струјама цурења. Добијени резултати недвосмислено указују да истакнути композит може бити успешно примењен као функционални мултифероик.
PB  - Association for ETRAN Society
T2  - Science of Sintering
T1  - Understanding the  Effect of Synthesis and Sintering Temperature on the Functional Properties of Barium Titanate/ Cobalt Ferrite  Composites
VL  - 55
SP  - 367
EP  - 381
DO  - 10.2298/SOS220512013S
ER  - 

@article{
author = "Šuljagić, Marija and Kremenović, Aleksandar and Petronijević, Ivan and Džunuzović, Adis and Mirković, Miljana and Pavlović, Vladimir and Anđelković, Ljubica",
year = "2023",
abstract = "To investigate the effect of synthesis procedure and sintering temperature on the functional properties of perovskite/spinel ceramics, BaTiO3/CoFe2O4 composites were prepared by thermal decomposition, coprecipitation, and microemulsion method, and sintered at 1150°C and 1300°C. The phase composition and morphology of as-prepared powders as well as sintered ceramics were thoroughly examined by X-ray powder diffraction (XRPD) and scanning electron microscopy (SEM) coupled with electron dispersive spectroscopy (EDS). The dielectric and ferroelectric measurements were performed in detail. Generally, the samples sintered at 1300°C had better performances than those sintered at 1150°C. The composite synthesized by thermal decomposition and sintered at 1300 °C stands out among other prepared BaTiO3/CoFe2O4 ceramics, owing to high stability in the wide frequency range and low leakage currents. The obtained results indicate that such composite might be successfully applied as a functional multiferroic., У циљу испитивања утицаја методе синтезе као и температуре синтеровања на функционална својства керамике перовскитно/спинелне структуре, синтетисани су BaTiO3/CoFe2O4 композити методама термалне декомпозиције, копреципитације и микроемулзије, а затим синтеровани на 1150 °C и 1300 °C. Фазни састав и морфологија синтетисаних узорака детаљно су испитани пре и после синтеровања помоћу рендгенске дифракције на праху (XRPD) и скенирајуће електронске микроскпије (SEM) спрегнуте са елекрон дисперзивном спектроскопијом (EDS). Изведена су опсежна испитивања како диелектричних, тако и фероелектричних својстава датих композита. У већини случајева узорци синтеровани на 1300 °C показали су боља својства од узорака синтерованих на 1150 °C. Композит синтетисан методом термалне декомпозиције и синтерован на 1300 °C издваја се од осталих синтетисаних BaTiO3/CoFe2O4 узорака захваљујући великој стабилносту у широком фреквентном опсегу и малим струјама цурења. Добијени резултати недвосмислено указују да истакнути композит може бити успешно примењен као функционални мултифероик.",
publisher = "Association for ETRAN Society",
journal = "Science of Sintering",
title = "Understanding the  Effect of Synthesis and Sintering Temperature on the Functional Properties of Barium Titanate/ Cobalt Ferrite  Composites",
volume = "55",
pages = "367-381",
doi = "10.2298/SOS220512013S"
}

Šuljagić, M., Kremenović, A., Petronijević, I., Džunuzović, A., Mirković, M., Pavlović, V.,& Anđelković, L.. (2023). Understanding the  Effect of Synthesis and Sintering Temperature on the Functional Properties of Barium Titanate/ Cobalt Ferrite  Composites. in Science of Sintering
Association for ETRAN Society., 55, 367-381.
https://doi.org/10.2298/SOS220512013S

Šuljagić M, Kremenović A, Petronijević I, Džunuzović A, Mirković M, Pavlović V, Anđelković L. Understanding the  Effect of Synthesis and Sintering Temperature on the Functional Properties of Barium Titanate/ Cobalt Ferrite  Composites. in Science of Sintering. 2023;55:367-381.
doi:10.2298/SOS220512013S .

Šuljagić, Marija, Kremenović, Aleksandar, Petronijević, Ivan, Džunuzović, Adis, Mirković, Miljana, Pavlović, Vladimir, Anđelković, Ljubica, "Understanding the  Effect of Synthesis and Sintering Temperature on the Functional Properties of Barium Titanate/ Cobalt Ferrite  Composites" in Science of Sintering, 55 (2023):367-381,
https://doi.org/10.2298/SOS220512013S . .

TY  - JOUR
AU  - Kremenović, Aleksandar
AU  - Grujić-Brojčin, Mirjana
AU  - Tomić, Nataša
AU  - Lazović, Vladimir
AU  - Bajuk-Bogdanović, Danica
AU  - Krstić, Jugoslav
AU  - Šćepanović, Maja
PY  - 2022
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/5424
AB  - A size-strain line-broadening analysis of the XRPD patterns and Raman spectra for two anatase/brookite (TiO2)-based nanocomposites with carbon (C) was carried out and the results compared with those of a similar sample free of carbon. The crystal structures and microstructures of anatase and brookite, as well as their relative abundance ratio, have been refined from XRPD data by the Rietveld method (the low amount of carbon is neglected). The XRPD size-strain analysis resulted in reliable structure and microstructure results for both anatase and brookite. The experimental Raman spectra of all the samples in the region 100-200 cm-1are dominated by a strong feature primarily composed of the most intense modes of anatase (Eg ) and brookite (A 1g ). The anatase crystallite sizes of 14-17 nm, estimated by XRPD, suggest the application of the phonon confinement model (PCM) for the analysis of the anatase Eg mode, whereas the relatively large brookite crystallite size (27-29 nm) does not imply the use of the PCM for the brookite A 1g mode. Superposition of the anatase Eg mode profile, calculated by the PCM, and the Lorentzian shape of the brookite A 1g mode provide an appropriate simulation of the change in the dominant Raman feature in the spectra of TiO2-based nanocomposites with carbon. Raman spectra measured in the high-frequency range (1000-2000 cm-1) provide information on carbon in the investigated nanocomposite materials. The results from field-emission scanning electron microscope (SEM), thermogravimetric analysis (TGA), Fourier transform infrared (FTIR) spectroscopy and nitrogen physisorption measurements support the XRPD and Raman results.
PB  - UK : International Union of Crystallography
T2  - Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials
T1  - Size-strain line-broadening analysis of anatase/brookite (TiO2)-based nanocomposites with carbon (C): XRPD and Raman spectroscopic analysis
VL  - 78
SP  - 214
EP  - 222
DO  - 10.1107/S2052520622001731
ER  - 

@article{
author = "Kremenović, Aleksandar and Grujić-Brojčin, Mirjana and Tomić, Nataša and Lazović, Vladimir and Bajuk-Bogdanović, Danica and Krstić, Jugoslav and Šćepanović, Maja",
year = "2022",
abstract = "A size-strain line-broadening analysis of the XRPD patterns and Raman spectra for two anatase/brookite (TiO2)-based nanocomposites with carbon (C) was carried out and the results compared with those of a similar sample free of carbon. The crystal structures and microstructures of anatase and brookite, as well as their relative abundance ratio, have been refined from XRPD data by the Rietveld method (the low amount of carbon is neglected). The XRPD size-strain analysis resulted in reliable structure and microstructure results for both anatase and brookite. The experimental Raman spectra of all the samples in the region 100-200 cm-1are dominated by a strong feature primarily composed of the most intense modes of anatase (Eg ) and brookite (A 1g ). The anatase crystallite sizes of 14-17 nm, estimated by XRPD, suggest the application of the phonon confinement model (PCM) for the analysis of the anatase Eg mode, whereas the relatively large brookite crystallite size (27-29 nm) does not imply the use of the PCM for the brookite A 1g mode. Superposition of the anatase Eg mode profile, calculated by the PCM, and the Lorentzian shape of the brookite A 1g mode provide an appropriate simulation of the change in the dominant Raman feature in the spectra of TiO2-based nanocomposites with carbon. Raman spectra measured in the high-frequency range (1000-2000 cm-1) provide information on carbon in the investigated nanocomposite materials. The results from field-emission scanning electron microscope (SEM), thermogravimetric analysis (TGA), Fourier transform infrared (FTIR) spectroscopy and nitrogen physisorption measurements support the XRPD and Raman results.",
publisher = "UK : International Union of Crystallography",
journal = "Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials",
title = "Size-strain line-broadening analysis of anatase/brookite (TiO2)-based nanocomposites with carbon (C): XRPD and Raman spectroscopic analysis",
volume = "78",
pages = "214-222",
doi = "10.1107/S2052520622001731"
}

Kremenović, A., Grujić-Brojčin, M., Tomić, N., Lazović, V., Bajuk-Bogdanović, D., Krstić, J.,& Šćepanović, M.. (2022). Size-strain line-broadening analysis of anatase/brookite (TiO2)-based nanocomposites with carbon (C): XRPD and Raman spectroscopic analysis. in Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials
UK : International Union of Crystallography., 78, 214-222.
https://doi.org/10.1107/S2052520622001731

Kremenović A, Grujić-Brojčin M, Tomić N, Lazović V, Bajuk-Bogdanović D, Krstić J, Šćepanović M. Size-strain line-broadening analysis of anatase/brookite (TiO2)-based nanocomposites with carbon (C): XRPD and Raman spectroscopic analysis. in Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials. 2022;78:214-222.
doi:10.1107/S2052520622001731 .

Kremenović, Aleksandar, Grujić-Brojčin, Mirjana, Tomić, Nataša, Lazović, Vladimir, Bajuk-Bogdanović, Danica, Krstić, Jugoslav, Šćepanović, Maja, "Size-strain line-broadening analysis of anatase/brookite (TiO2)-based nanocomposites with carbon (C): XRPD and Raman spectroscopic analysis" in Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials, 78 (2022):214-222,
https://doi.org/10.1107/S2052520622001731 . .

TY  - JOUR
AU  - Tančić, Pavle
AU  - Kremenović, Aleksandar
PY  - 2022
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/5883
AB  - Four macroscopically visible B–E (rim) zones, within a large natural ferric grossular garnet of Grs58–64Adr36–42Sps2 composition, are described by means of Rietveld refinements of the crystal structures in a series of six space groups, followed by comparative analysis of the R-values, site occupancy factors, and bond lengths and angles. The garnet crystallized in the rhombohedral R-3c space group. Various polyhedral distortions and structural order-disorder variations between the zones studied are also described and discussed. The rhombohedral symmetry of the ferric grossular garnet analysed can be regarded as primary, residual strain being a secondary cause for its slight optical anisotropy.
PB  - Polish Geological Institute - National Research Institute
T2  - Geological Quarterly
T1  - Rietveld crystal structure refinement of a natural rhombohedral grossular-andradite garnet from Serbia
VL  - 66
IS  - 1
SP  - 7
DO  - 10.7306/gq.1639
ER  - 

@article{
author = "Tančić, Pavle and Kremenović, Aleksandar",
year = "2022",
abstract = "Four macroscopically visible B–E (rim) zones, within a large natural ferric grossular garnet of Grs58–64Adr36–42Sps2 composition, are described by means of Rietveld refinements of the crystal structures in a series of six space groups, followed by comparative analysis of the R-values, site occupancy factors, and bond lengths and angles. The garnet crystallized in the rhombohedral R-3c space group. Various polyhedral distortions and structural order-disorder variations between the zones studied are also described and discussed. The rhombohedral symmetry of the ferric grossular garnet analysed can be regarded as primary, residual strain being a secondary cause for its slight optical anisotropy.",
publisher = "Polish Geological Institute - National Research Institute",
journal = "Geological Quarterly",
title = "Rietveld crystal structure refinement of a natural rhombohedral grossular-andradite garnet from Serbia",
volume = "66",
number = "1",
pages = "7",
doi = "10.7306/gq.1639"
}

Tančić, P.,& Kremenović, A.. (2022). Rietveld crystal structure refinement of a natural rhombohedral grossular-andradite garnet from Serbia. in Geological Quarterly
Polish Geological Institute - National Research Institute., 66(1), 7.
https://doi.org/10.7306/gq.1639

Tančić P, Kremenović A. Rietveld crystal structure refinement of a natural rhombohedral grossular-andradite garnet from Serbia. in Geological Quarterly. 2022;66(1):7.
doi:10.7306/gq.1639 .

Tančić, Pavle, Kremenović, Aleksandar, "Rietveld crystal structure refinement of a natural rhombohedral grossular-andradite garnet from Serbia" in Geological Quarterly, 66, no. 1 (2022):7,
https://doi.org/10.7306/gq.1639 . .

TY  - JOUR
AU  - Mitrović, Jelena
AU  - Divović-Matović, Branka
AU  - Knutson, Daniel E.
AU  - Ðoković, Jelena B.
AU  - Kremenović, Aleksandar
AU  - Dobričić, Vladimir
AU  - Randjelović, Danijela
AU  - Pantelić, Ivana
AU  - Cook, James
AU  - Savić, Miroslav M.
AU  - Savić, Snežana D.
PY  - 2021
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/4791
AB  - Poor water solubility of new chemical entities is considered as one of the main obstacles in drug development, as it usually leads to low bioavailability after administration. To overcome these problems, the selection of the appropriate formulation technology needs to be based on the physicochemical properties of the drug and introduced in the early stages of drug research. One example of the new potential drug substance with poor solubility is DK-I-60-3, deuterated pyrazoloquinolinone, designed for the treatment of various neuropsychiatric disorders. In this research, based on preformulation studies, nanocrystal technology was chosen to improve the oral bioavailability of DK-I-60-3. Nanocrystal dispersions stabilized by sodium lauryl sulfate and polyvinylpyrrolidone were prepared by modified wet media milling technique, with the selection of appropriate process and formulation parameters. The nanoparticles characterization included particle size and zeta potential measurements, differential scanning calorimetry, X-ray powder diffraction, dissolution and solubility study, and in vivo pharmacokinetic experiments. Developed formulations had small uniform particle sizes and were stable for three months. Nanonization caused decreased crystallite size and induced crystal defects formation, as well as a DK-I-60-3 solubility increase. Furthermore, after oral administration of the developed formulations in rats, two to three-fold bioavailability enhancement was observed in plasma and investigated organs, including the brain.
PB  - MDPI
T2  - Pharmaceutics
T1  - Overcoming the low oral bioavailability of deuterated pyrazoloquinolinone ligand dk-i-60-3 by nanonization: A knowledge-based approach
VL  - 13
IS  - 8
SP  - 1188
DO  - 10.3390/pharmaceutics13081188
ER  - 

@article{
author = "Mitrović, Jelena and Divović-Matović, Branka and Knutson, Daniel E. and Ðoković, Jelena B. and Kremenović, Aleksandar and Dobričić, Vladimir and Randjelović, Danijela and Pantelić, Ivana and Cook, James and Savić, Miroslav M. and Savić, Snežana D.",
year = "2021",
abstract = "Poor water solubility of new chemical entities is considered as one of the main obstacles in drug development, as it usually leads to low bioavailability after administration. To overcome these problems, the selection of the appropriate formulation technology needs to be based on the physicochemical properties of the drug and introduced in the early stages of drug research. One example of the new potential drug substance with poor solubility is DK-I-60-3, deuterated pyrazoloquinolinone, designed for the treatment of various neuropsychiatric disorders. In this research, based on preformulation studies, nanocrystal technology was chosen to improve the oral bioavailability of DK-I-60-3. Nanocrystal dispersions stabilized by sodium lauryl sulfate and polyvinylpyrrolidone were prepared by modified wet media milling technique, with the selection of appropriate process and formulation parameters. The nanoparticles characterization included particle size and zeta potential measurements, differential scanning calorimetry, X-ray powder diffraction, dissolution and solubility study, and in vivo pharmacokinetic experiments. Developed formulations had small uniform particle sizes and were stable for three months. Nanonization caused decreased crystallite size and induced crystal defects formation, as well as a DK-I-60-3 solubility increase. Furthermore, after oral administration of the developed formulations in rats, two to three-fold bioavailability enhancement was observed in plasma and investigated organs, including the brain.",
publisher = "MDPI",
journal = "Pharmaceutics",
title = "Overcoming the low oral bioavailability of deuterated pyrazoloquinolinone ligand dk-i-60-3 by nanonization: A knowledge-based approach",
volume = "13",
number = "8",
pages = "1188",
doi = "10.3390/pharmaceutics13081188"
}

Mitrović, J., Divović-Matović, B., Knutson, D. E., Ðoković, J. B., Kremenović, A., Dobričić, V., Randjelović, D., Pantelić, I., Cook, J., Savić, M. M.,& Savić, S. D.. (2021). Overcoming the low oral bioavailability of deuterated pyrazoloquinolinone ligand dk-i-60-3 by nanonization: A knowledge-based approach. in Pharmaceutics
MDPI., 13(8), 1188.
https://doi.org/10.3390/pharmaceutics13081188

Mitrović J, Divović-Matović B, Knutson DE, Ðoković JB, Kremenović A, Dobričić V, Randjelović D, Pantelić I, Cook J, Savić MM, Savić SD. Overcoming the low oral bioavailability of deuterated pyrazoloquinolinone ligand dk-i-60-3 by nanonization: A knowledge-based approach. in Pharmaceutics. 2021;13(8):1188.
doi:10.3390/pharmaceutics13081188 .

Mitrović, Jelena, Divović-Matović, Branka, Knutson, Daniel E., Ðoković, Jelena B., Kremenović, Aleksandar, Dobričić, Vladimir, Randjelović, Danijela, Pantelić, Ivana, Cook, James, Savić, Miroslav M., Savić, Snežana D., "Overcoming the low oral bioavailability of deuterated pyrazoloquinolinone ligand dk-i-60-3 by nanonization: A knowledge-based approach" in Pharmaceutics, 13, no. 8 (2021):1188,
https://doi.org/10.3390/pharmaceutics13081188 . .

TY  - JOUR
AU  - Nikolić, Ines
AU  - Antić-Stanković, Jelena
AU  - Božić, Dragana
AU  - Randjelović, Danijela
AU  - Marković, Bojan D.
AU  - Lunter, Dominique Jasmin
AU  - Kremenović, Aleksandar
AU  - Savić, Miroslav M.
AU  - Savić, Snežana
PY  - 2020
UR  - https://farfar.pharmacy.bg.ac.rs/handle/123456789/3711
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/3720
AB  - As the number of poorly soluble drugs is increasing, nanocrystals have become very interesting due to wide range of application possibilities. Curcuminwas used as a model active ingredient in this work. Even though it has many proven positive effects, due to its physicochemical issues, its possibilities have not been fully exploited. The goal of this work was to select optimal conditions for a top-down method for curcumin nanosuspension production, and to perform their comprehensive characterization applying complementary methodologies: dynamic light scattering, polarization and atomic force microscopy, thermal analysis, X-ray powder diffraction, antioxidant activity evaluation, release kinetics assessment, and screening of potential biological effects applying cell viability assays on normal human lung fibroblasts, human melanoma and human adenomacarcinoma cells. After 30 min of milling, nanosuspensions stabilized by polysorbate 80 and by its combinations with sucrose palmitate showed good stability, while curcumin crystal structure was unaltered. Obtained nanocrystals were well defined, with average diameter 120-170 nm and PDI of about 0.25, zeta potential was below -30 mV and pH~5 for all formulations. Nanodispersions exhibited high antioxidant potential and improved dissolution rate compared to the corresponding coarse dispersions. Although curcumin nanodispersions exhibited significant antiproliferative effect to each cancer cell line, the highest effect was towards adenocarcinoma cells.
PB  - Walter de Gruyter GmbH
T2  - Reviews on Advanced Materials Science
T1  - Curcumin Nanonization Using An Alternative Small-Scale Production Unit: Selection of Proper Stabilizer Applying Basic Physicochemical Consideration and Biological Activity Assessment of Nanocrystals
VL  - 59
IS  - 1
SP  - 406
EP  - 424
DO  - 10.1515/rams-2020-0043
ER  - 

@article{
author = "Nikolić, Ines and Antić-Stanković, Jelena and Božić, Dragana and Randjelović, Danijela and Marković, Bojan D. and Lunter, Dominique Jasmin and Kremenović, Aleksandar and Savić, Miroslav M. and Savić, Snežana",
year = "2020",
abstract = "As the number of poorly soluble drugs is increasing, nanocrystals have become very interesting due to wide range of application possibilities. Curcuminwas used as a model active ingredient in this work. Even though it has many proven positive effects, due to its physicochemical issues, its possibilities have not been fully exploited. The goal of this work was to select optimal conditions for a top-down method for curcumin nanosuspension production, and to perform their comprehensive characterization applying complementary methodologies: dynamic light scattering, polarization and atomic force microscopy, thermal analysis, X-ray powder diffraction, antioxidant activity evaluation, release kinetics assessment, and screening of potential biological effects applying cell viability assays on normal human lung fibroblasts, human melanoma and human adenomacarcinoma cells. After 30 min of milling, nanosuspensions stabilized by polysorbate 80 and by its combinations with sucrose palmitate showed good stability, while curcumin crystal structure was unaltered. Obtained nanocrystals were well defined, with average diameter 120-170 nm and PDI of about 0.25, zeta potential was below -30 mV and pH~5 for all formulations. Nanodispersions exhibited high antioxidant potential and improved dissolution rate compared to the corresponding coarse dispersions. Although curcumin nanodispersions exhibited significant antiproliferative effect to each cancer cell line, the highest effect was towards adenocarcinoma cells.",
publisher = "Walter de Gruyter GmbH",
journal = "Reviews on Advanced Materials Science",
title = "Curcumin Nanonization Using An Alternative Small-Scale Production Unit: Selection of Proper Stabilizer Applying Basic Physicochemical Consideration and Biological Activity Assessment of Nanocrystals",
volume = "59",
number = "1",
pages = "406-424",
doi = "10.1515/rams-2020-0043"
}

Nikolić, I., Antić-Stanković, J., Božić, D., Randjelović, D., Marković, B. D., Lunter, D. J., Kremenović, A., Savić, M. M.,& Savić, S.. (2020). Curcumin Nanonization Using An Alternative Small-Scale Production Unit: Selection of Proper Stabilizer Applying Basic Physicochemical Consideration and Biological Activity Assessment of Nanocrystals. in Reviews on Advanced Materials Science
Walter de Gruyter GmbH., 59(1), 406-424.
https://doi.org/10.1515/rams-2020-0043

Nikolić I, Antić-Stanković J, Božić D, Randjelović D, Marković BD, Lunter DJ, Kremenović A, Savić MM, Savić S. Curcumin Nanonization Using An Alternative Small-Scale Production Unit: Selection of Proper Stabilizer Applying Basic Physicochemical Consideration and Biological Activity Assessment of Nanocrystals. in Reviews on Advanced Materials Science. 2020;59(1):406-424.
doi:10.1515/rams-2020-0043 .

Nikolić, Ines, Antić-Stanković, Jelena, Božić, Dragana, Randjelović, Danijela, Marković, Bojan D., Lunter, Dominique Jasmin, Kremenović, Aleksandar, Savić, Miroslav M., Savić, Snežana, "Curcumin Nanonization Using An Alternative Small-Scale Production Unit: Selection of Proper Stabilizer Applying Basic Physicochemical Consideration and Biological Activity Assessment of Nanocrystals" in Reviews on Advanced Materials Science, 59, no. 1 (2020):406-424,
https://doi.org/10.1515/rams-2020-0043 . .

TY  - JOUR
AU  - Tančić, Pavle
AU  - Kremenović, Aleksandar
AU  - Vulić, Predrag
PY  - 2020
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/5895
AB  - In this paper, grandite core with Grs64±1Adr36±1Sps2 composition was crystallographically studied. This core represents zone A of the macroscopically visible five A–E zones of the optically anisotropic Grs58–64Adr36–42Sps2 grandite. The applied procedure includes the detailed analysis of the powder diffraction patterns, and the Rietveld refinements of the crystal structures in a series of 18 space groups and two mixtures, which were followed by the comparative analysis of the R-values, site occupancy factors, and the bond lengths and angles. Synthesis of all of the presented results allows us to undoubtedly conclude that studied grandite is not cubic, neither as monophase nor as multiple phases in a mixture. Namely, it was established that structural dissymmetrization occurred and that it crystallized in the disordered rhombohedral R-3c or orthorhombic Fddd space groups, whereby the first one is more probable. Beside the established lower symmetry of the studied grandite, which could be treated as the primary cause, the residual strain is also not excluded as the second possible cause for its slight optical anisotropy.
PB  - Cambridge University Press
T2  - Powder Diffraction
T1  - Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia)
VL  - 35
IS  - 1
SP  - 7
EP  - 16
DO  - 10.1017/S0885715619000897
ER  - 

@article{
author = "Tančić, Pavle and Kremenović, Aleksandar and Vulić, Predrag",
year = "2020",
abstract = "In this paper, grandite core with Grs64±1Adr36±1Sps2 composition was crystallographically studied. This core represents zone A of the macroscopically visible five A–E zones of the optically anisotropic Grs58–64Adr36–42Sps2 grandite. The applied procedure includes the detailed analysis of the powder diffraction patterns, and the Rietveld refinements of the crystal structures in a series of 18 space groups and two mixtures, which were followed by the comparative analysis of the R-values, site occupancy factors, and the bond lengths and angles. Synthesis of all of the presented results allows us to undoubtedly conclude that studied grandite is not cubic, neither as monophase nor as multiple phases in a mixture. Namely, it was established that structural dissymmetrization occurred and that it crystallized in the disordered rhombohedral R-3c or orthorhombic Fddd space groups, whereby the first one is more probable. Beside the established lower symmetry of the studied grandite, which could be treated as the primary cause, the residual strain is also not excluded as the second possible cause for its slight optical anisotropy.",
publisher = "Cambridge University Press",
journal = "Powder Diffraction",
title = "Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia)",
volume = "35",
number = "1",
pages = "7-16",
doi = "10.1017/S0885715619000897"
}

Tančić, P., Kremenović, A.,& Vulić, P.. (2020). Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia). in Powder Diffraction
Cambridge University Press., 35(1), 7-16.
https://doi.org/10.1017/S0885715619000897

Tančić P, Kremenović A, Vulić P. Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia). in Powder Diffraction. 2020;35(1):7-16.
doi:10.1017/S0885715619000897 .

Tančić, Pavle, Kremenović, Aleksandar, Vulić, Predrag, "Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia)" in Powder Diffraction, 35, no. 1 (2020):7-16,
https://doi.org/10.1017/S0885715619000897 . .

TY  - DATA
AU  - Tančić, Pavle
AU  - Kremenović, Aleksandar
AU  - Vulić, Predrag
PY  - 2020
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6978
AB  - Supplementary 1. Chemical compositions, β0-90° values, degrees of ordering (m), intersite distribution coefficients (K1–2) and space groups of low symmetry grandite samples. Supplementary 2. Atom parameters (in Å) and calculated Ca and Al sof’s (at. %) for the cubic Ia‾3d space group (without and with constraints). Supplementary 3. Selected distances (in Å) and angles (in °) for the cubic Ia‾3d space group (without and with constraints). Supplementary 4. Unit cell dimensions and calculated Ca and Al sof’s (at. %) for all of the studied space groups and mixtures (without and with constraints). Supplementary 5. Calculated 4 × c0/a0 and α values for the rhombohedral R‾3c and R‾3 space groups (without and with constraints). Supplementary 6. Criterions (I) for the space group determination. Distances are given in Å; and Al and Ca sof’s in at. %. Supplementary 7. Distribution of the average cation ratios at X and Y sites of the non-cubic garnets (after Griffen et al., 1992), with the position of the grandite studied in this paper (marked as MP-Meka Presedla). Supplementary 8. Criterions (II) for the space group determination. Distances are given in Å; and Al and Ca sof’s in at. %. Supplementary 9. Atom parameters (in Å) and calculated Ca and Al sof’s (at. %) for the rhombohedral R‾3c space group (without and with constraints). Supplementary 10. Selected distances (in Å) and angles (in °) for the rhombohedral R‾3c space group (without and with constraints). Supplementary 11. Atom parameters (in Å) and calculated Ca and Al sof’s (at. %) for the orthorhombic Fddd space group (without and with constraints). Supplementary 12. Selected distances (in Å) and angles (in °) for the orthorhombic Fddd space group (without and with constraints). Supplementary 13. Calculated polyhedral volumes, quadratic elongations and angle variances in the tetrahedron and octahedron for the Ia‾3d, R‾3c and Fddd space groups (without and with constraints). Adequate values for grossular (Grs) and andradite (Adr), were also added for comparison. Supplementary 14. Criterions (III) for the space group determination. Distances are given in Å, and angles in °. Supplementary 15. Criterions (IV) for the space group determination. Distances are given in Å, and Al sof’s in at. %. Supplementary 16. Number (No) of calculated Bragg’s positions (Ycalc) and differences between starting and ending corresponding Ycalc’s (ΔYcalc). All reflections are marked with hkl’s belonging to the Ia‾3d space group (see Figures 3 and 4). Single peaks are marked with “-“, and doublets with “+” signs.
PB  - Cambridge University Press
T2  - Powder Diffraction
T1  - Supplementary Materials for: "Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia)"
UR  - https://hdl.handle.net/21.15107/rcub_cer_6978
ER  - 

@misc{
author = "Tančić, Pavle and Kremenović, Aleksandar and Vulić, Predrag",
year = "2020",
abstract = "Supplementary 1. Chemical compositions, β0-90° values, degrees of ordering (m), intersite distribution coefficients (K1–2) and space groups of low symmetry grandite samples. Supplementary 2. Atom parameters (in Å) and calculated Ca and Al sof’s (at. %) for the cubic Ia‾3d space group (without and with constraints). Supplementary 3. Selected distances (in Å) and angles (in °) for the cubic Ia‾3d space group (without and with constraints). Supplementary 4. Unit cell dimensions and calculated Ca and Al sof’s (at. %) for all of the studied space groups and mixtures (without and with constraints). Supplementary 5. Calculated 4 × c0/a0 and α values for the rhombohedral R‾3c and R‾3 space groups (without and with constraints). Supplementary 6. Criterions (I) for the space group determination. Distances are given in Å; and Al and Ca sof’s in at. %. Supplementary 7. Distribution of the average cation ratios at X and Y sites of the non-cubic garnets (after Griffen et al., 1992), with the position of the grandite studied in this paper (marked as MP-Meka Presedla). Supplementary 8. Criterions (II) for the space group determination. Distances are given in Å; and Al and Ca sof’s in at. %. Supplementary 9. Atom parameters (in Å) and calculated Ca and Al sof’s (at. %) for the rhombohedral R‾3c space group (without and with constraints). Supplementary 10. Selected distances (in Å) and angles (in °) for the rhombohedral R‾3c space group (without and with constraints). Supplementary 11. Atom parameters (in Å) and calculated Ca and Al sof’s (at. %) for the orthorhombic Fddd space group (without and with constraints). Supplementary 12. Selected distances (in Å) and angles (in °) for the orthorhombic Fddd space group (without and with constraints). Supplementary 13. Calculated polyhedral volumes, quadratic elongations and angle variances in the tetrahedron and octahedron for the Ia‾3d, R‾3c and Fddd space groups (without and with constraints). Adequate values for grossular (Grs) and andradite (Adr), were also added for comparison. Supplementary 14. Criterions (III) for the space group determination. Distances are given in Å, and angles in °. Supplementary 15. Criterions (IV) for the space group determination. Distances are given in Å, and Al sof’s in at. %. Supplementary 16. Number (No) of calculated Bragg’s positions (Ycalc) and differences between starting and ending corresponding Ycalc’s (ΔYcalc). All reflections are marked with hkl’s belonging to the Ia‾3d space group (see Figures 3 and 4). Single peaks are marked with “-“, and doublets with “+” signs.",
publisher = "Cambridge University Press",
journal = "Powder Diffraction",
title = "Supplementary Materials for: "Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia)"",
url = "https://hdl.handle.net/21.15107/rcub_cer_6978"
}

Tančić, P., Kremenović, A.,& Vulić, P.. (2020). Supplementary Materials for: "Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia)". in Powder Diffraction
Cambridge University Press..
https://hdl.handle.net/21.15107/rcub_cer_6978

Tančić P, Kremenović A, Vulić P. Supplementary Materials for: "Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia)". in Powder Diffraction. 2020;.
https://hdl.handle.net/21.15107/rcub_cer_6978 .

Tančić, Pavle, Kremenović, Aleksandar, Vulić, Predrag, "Supplementary Materials for: "Structural dissymmetrization of optically anisotropic Grs64±1Adr36±1Sps2 grandite from Meka Presedla (Kopaonik Mt., Serbia)"" in Powder Diffraction (2020),
https://hdl.handle.net/21.15107/rcub_cer_6978 .

TY  - JOUR
AU  - Finčur, Nina L.
AU  - Šćepanović, Maja
AU  - Grujić-Brojčin, Mirjana
AU  - Abramović, Biljana F.
AU  - Krstić, Jugoslav
AU  - Kremenović, Aleksandar
AU  - Srećković, Tatjana
AU  - Golubović, Aleksandar
PY  - 2019
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/3025
AB  - Mesoporous anatase nanopowders were doped with 0.05−0.5 mol% of W6+, in order to obtain more efficient photocatalyst than TiO2 Degussa P25 in the degradation of amitriptyline (AMI) under simulated solar irradiation (SSI). Dominant XRPD peaks were ascribed to anatase phase, with additional peaks which could correspond to brookite, TiO2 bronze and sodium titanate, Na2Ti9O19. The Raman scattering measurements have confirmed anatase as dominant phase, with broad Raman feature at ~270 cm−1 possibly related to Ti–O–Na stretching vibration. All W-doped nanopowders have shown enhanced adsorption and higher efficiency in photodegradation of AMI in comparison to TiO2 Degussa P25 under the same conditions. The catalyst doped with 0.4 mol% of W6+, which has shown the highest efficiency in degradation of AMI under SSI, has
also been tested in degradation of alprazolam (ALP). The effect of substrate type (AMI and ALP), catalyst loading, and initial substrate concentration on photocatalytic degradation using SSI was examined. The identification of the species responsible for the photocatalytic degradation of AMI and ALP by the catalyst doped with 0.4 mol% of W6+ was performed in the presence of various scavengers under SSI. The major role in degradation of AMI may be attributed to hydroxyl radicals, whereas superoxide anion radicals, singlet molecular oxygen and hydroxyl radicals contribute to degradation of ALP.
PB  - Springer
T2  - Journal of Sol-Gel Science and Technology
T1  - Adsorption and degradation of some psychiatric drugs by sol-gel synthesized titania-based photocatalysts: influence of tungsten and sodium content
VL  - 90
IS  - 3
SP  - 510
EP  - 524
DO  - 10.1007/s10971-019-04925-4
ER  - 

@article{
author = "Finčur, Nina L. and Šćepanović, Maja and Grujić-Brojčin, Mirjana and Abramović, Biljana F. and Krstić, Jugoslav and Kremenović, Aleksandar and Srećković, Tatjana and Golubović, Aleksandar",
year = "2019",
abstract = "Mesoporous anatase nanopowders were doped with 0.05−0.5 mol% of W6+, in order to obtain more efficient photocatalyst than TiO2 Degussa P25 in the degradation of amitriptyline (AMI) under simulated solar irradiation (SSI). Dominant XRPD peaks were ascribed to anatase phase, with additional peaks which could correspond to brookite, TiO2 bronze and sodium titanate, Na2Ti9O19. The Raman scattering measurements have confirmed anatase as dominant phase, with broad Raman feature at ~270 cm−1 possibly related to Ti–O–Na stretching vibration. All W-doped nanopowders have shown enhanced adsorption and higher efficiency in photodegradation of AMI in comparison to TiO2 Degussa P25 under the same conditions. The catalyst doped with 0.4 mol% of W6+, which has shown the highest efficiency in degradation of AMI under SSI, has
also been tested in degradation of alprazolam (ALP). The effect of substrate type (AMI and ALP), catalyst loading, and initial substrate concentration on photocatalytic degradation using SSI was examined. The identification of the species responsible for the photocatalytic degradation of AMI and ALP by the catalyst doped with 0.4 mol% of W6+ was performed in the presence of various scavengers under SSI. The major role in degradation of AMI may be attributed to hydroxyl radicals, whereas superoxide anion radicals, singlet molecular oxygen and hydroxyl radicals contribute to degradation of ALP.",
publisher = "Springer",
journal = "Journal of Sol-Gel Science and Technology",
title = "Adsorption and degradation of some psychiatric drugs by sol-gel synthesized titania-based photocatalysts: influence of tungsten and sodium content",
volume = "90",
number = "3",
pages = "510-524",
doi = "10.1007/s10971-019-04925-4"
}

Finčur, N. L., Šćepanović, M., Grujić-Brojčin, M., Abramović, B. F., Krstić, J., Kremenović, A., Srećković, T.,& Golubović, A.. (2019). Adsorption and degradation of some psychiatric drugs by sol-gel synthesized titania-based photocatalysts: influence of tungsten and sodium content. in Journal of Sol-Gel Science and Technology
Springer., 90(3), 510-524.
https://doi.org/10.1007/s10971-019-04925-4

Finčur NL, Šćepanović M, Grujić-Brojčin M, Abramović BF, Krstić J, Kremenović A, Srećković T, Golubović A. Adsorption and degradation of some psychiatric drugs by sol-gel synthesized titania-based photocatalysts: influence of tungsten and sodium content. in Journal of Sol-Gel Science and Technology. 2019;90(3):510-524.
doi:10.1007/s10971-019-04925-4 .

Finčur, Nina L., Šćepanović, Maja, Grujić-Brojčin, Mirjana, Abramović, Biljana F., Krstić, Jugoslav, Kremenović, Aleksandar, Srećković, Tatjana, Golubović, Aleksandar, "Adsorption and degradation of some psychiatric drugs by sol-gel synthesized titania-based photocatalysts: influence of tungsten and sodium content" in Journal of Sol-Gel Science and Technology, 90, no. 3 (2019):510-524,
https://doi.org/10.1007/s10971-019-04925-4 . .

TY  - JOUR
AU  - Dojčinović, Biljana
AU  - Jančar, Boštjan
AU  - Bessais, Lotfi
AU  - Kremenović, Aleksandar
AU  - Jović-Jovičić, Nataša
AU  - Banković, Predrag
AU  - Stanković, Dalibor
AU  - Ognjanović, Miloš
AU  - Antić, Bratislav
PY  - 2019
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/3243
AB  - Herein we report effects of partial substitution of Fe3+ by Y3+ in magnetite (Fe3O4) on morphology and inorganic arsenic species adsorption efficiency of the Fe3−x Y x O4 nanoparticles formed. The series of Fe3−x Y x O4 (x = 0.00, 0.042 and 0.084, labeled as Y00, Y05 and Y10, respectively) was synthesized using co-precipitation followed by microwave-hydrothermal treatment (MW) at 200 °C. With increase of yttrium content (x value), both the morphological inhomogeneity of the samples and the fraction of spinel nanorods as compared to spinel pseudospherical particles increased. By both transmission electron microscopy and x-ray powder diffraction analyses, it was determined that the direction of growth of the spinel nanorods is along the [110] crystallographic direction. The Fe3−x Y x O4 affinities of adsorption toward the inorganic arsenic species, As(III) (arsenite, AsO3 3−) and As(V) (arsenate, AsO4 3−), were investigated. Increased Y3+ content related to changes in sample morphology was followed by a decrease of As(III) removal efficiency and vice versa for As(V). The increase in Y3+ content, in addition to increasing the adsorption capacity for As(V), significantly expanded the optimum pH range for the maximum removal and decreased the contact time for necessary 50% removal (t 1/2) of As(V) (Y00: pH 2–3, t 1/2 = 3.12 min; Y05: pH 2–6, t 1/2 = 2.12 min and Y10: pH 2–10, t 1/2 = 1.12 min). The results point to incorporation of Y3+ in the crystal lattice of magnetite, inducing nanorod spinel structure formation with significant changes in sorption properties important for the removal of inorganic arsenic from waters.
PB  - IOP Publishing
T2  - Nanotechnology
T1  - Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species
VL  - 30
IS  - 47
SP  - 475702
DO  - 10.1088/1361-6528/ab3ca2
ER  - 

@article{
author = "Dojčinović, Biljana and Jančar, Boštjan and Bessais, Lotfi and Kremenović, Aleksandar and Jović-Jovičić, Nataša and Banković, Predrag and Stanković, Dalibor and Ognjanović, Miloš and Antić, Bratislav",
year = "2019",
abstract = "Herein we report effects of partial substitution of Fe3+ by Y3+ in magnetite (Fe3O4) on morphology and inorganic arsenic species adsorption efficiency of the Fe3−x Y x O4 nanoparticles formed. The series of Fe3−x Y x O4 (x = 0.00, 0.042 and 0.084, labeled as Y00, Y05 and Y10, respectively) was synthesized using co-precipitation followed by microwave-hydrothermal treatment (MW) at 200 °C. With increase of yttrium content (x value), both the morphological inhomogeneity of the samples and the fraction of spinel nanorods as compared to spinel pseudospherical particles increased. By both transmission electron microscopy and x-ray powder diffraction analyses, it was determined that the direction of growth of the spinel nanorods is along the [110] crystallographic direction. The Fe3−x Y x O4 affinities of adsorption toward the inorganic arsenic species, As(III) (arsenite, AsO3 3−) and As(V) (arsenate, AsO4 3−), were investigated. Increased Y3+ content related to changes in sample morphology was followed by a decrease of As(III) removal efficiency and vice versa for As(V). The increase in Y3+ content, in addition to increasing the adsorption capacity for As(V), significantly expanded the optimum pH range for the maximum removal and decreased the contact time for necessary 50% removal (t 1/2) of As(V) (Y00: pH 2–3, t 1/2 = 3.12 min; Y05: pH 2–6, t 1/2 = 2.12 min and Y10: pH 2–10, t 1/2 = 1.12 min). The results point to incorporation of Y3+ in the crystal lattice of magnetite, inducing nanorod spinel structure formation with significant changes in sorption properties important for the removal of inorganic arsenic from waters.",
publisher = "IOP Publishing",
journal = "Nanotechnology",
title = "Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species",
volume = "30",
number = "47",
pages = "475702",
doi = "10.1088/1361-6528/ab3ca2"
}

Dojčinović, B., Jančar, B., Bessais, L., Kremenović, A., Jović-Jovičić, N., Banković, P., Stanković, D., Ognjanović, M.,& Antić, B.. (2019). Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species. in Nanotechnology
IOP Publishing., 30(47), 475702.
https://doi.org/10.1088/1361-6528/ab3ca2

Dojčinović B, Jančar B, Bessais L, Kremenović A, Jović-Jovičić N, Banković P, Stanković D, Ognjanović M, Antić B. Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species. in Nanotechnology. 2019;30(47):475702.
doi:10.1088/1361-6528/ab3ca2 .

Dojčinović, Biljana, Jančar, Boštjan, Bessais, Lotfi, Kremenović, Aleksandar, Jović-Jovičić, Nataša, Banković, Predrag, Stanković, Dalibor, Ognjanović, Miloš, Antić, Bratislav, "Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species" in Nanotechnology, 30, no. 47 (2019):475702,
https://doi.org/10.1088/1361-6528/ab3ca2 . .

TY  - JOUR
AU  - Dojčinović, Biljana
AU  - Jančar, Boštjan
AU  - Bessais, Lotfi
AU  - Kremenović, Aleksandar
AU  - Jović-Jovičić, Nataša
AU  - Banković, Predrag
AU  - Stanković, Dalibor
AU  - Ognjanović, Miloš
AU  - Antić, Bratislav
PY  - 2019
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/3244
AB  - Herein we report effects of partial substitution of Fe3+ by Y3+ in magnetite (Fe3O4) on morphology and inorganic arsenic species adsorption efficiency of the Fe3−x Y x O4 nanoparticles formed. The series of Fe3−x Y x O4 (x = 0.00, 0.042 and 0.084, labeled as Y00, Y05 and Y10, respectively) was synthesized using co-precipitation followed by microwave-hydrothermal treatment (MW) at 200 °C. With increase of yttrium content (x value), both the morphological inhomogeneity of the samples and the fraction of spinel nanorods as compared to spinel pseudospherical particles increased. By both transmission electron microscopy and x-ray powder diffraction analyses, it was determined that the direction of growth of the spinel nanorods is along the [110] crystallographic direction. The Fe3−x Y x O4 affinities of adsorption toward the inorganic arsenic species, As(III) (arsenite, AsO3 3−) and As(V) (arsenate, AsO4 3−), were investigated. Increased Y3+ content related to changes in sample morphology was followed by a decrease of As(III) removal efficiency and vice versa for As(V). The increase in Y3+ content, in addition to increasing the adsorption capacity for As(V), significantly expanded the optimum pH range for the maximum removal and decreased the contact time for necessary 50% removal (t 1/2) of As(V) (Y00: pH 2–3, t 1/2 = 3.12 min; Y05: pH 2–6, t 1/2 = 2.12 min and Y10: pH 2–10, t 1/2 = 1.12 min). The results point to incorporation of Y3+ in the crystal lattice of magnetite, inducing nanorod spinel structure formation with significant changes in sorption properties important for the removal of inorganic arsenic from waters.
PB  - IOP Publishing
T2  - Nanotechnology
T1  - Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species
VL  - 30
IS  - 47
SP  - 475702
DO  - 10.1088/1361-6528/ab3ca2
ER  - 

@article{
author = "Dojčinović, Biljana and Jančar, Boštjan and Bessais, Lotfi and Kremenović, Aleksandar and Jović-Jovičić, Nataša and Banković, Predrag and Stanković, Dalibor and Ognjanović, Miloš and Antić, Bratislav",
year = "2019",
abstract = "Herein we report effects of partial substitution of Fe3+ by Y3+ in magnetite (Fe3O4) on morphology and inorganic arsenic species adsorption efficiency of the Fe3−x Y x O4 nanoparticles formed. The series of Fe3−x Y x O4 (x = 0.00, 0.042 and 0.084, labeled as Y00, Y05 and Y10, respectively) was synthesized using co-precipitation followed by microwave-hydrothermal treatment (MW) at 200 °C. With increase of yttrium content (x value), both the morphological inhomogeneity of the samples and the fraction of spinel nanorods as compared to spinel pseudospherical particles increased. By both transmission electron microscopy and x-ray powder diffraction analyses, it was determined that the direction of growth of the spinel nanorods is along the [110] crystallographic direction. The Fe3−x Y x O4 affinities of adsorption toward the inorganic arsenic species, As(III) (arsenite, AsO3 3−) and As(V) (arsenate, AsO4 3−), were investigated. Increased Y3+ content related to changes in sample morphology was followed by a decrease of As(III) removal efficiency and vice versa for As(V). The increase in Y3+ content, in addition to increasing the adsorption capacity for As(V), significantly expanded the optimum pH range for the maximum removal and decreased the contact time for necessary 50% removal (t 1/2) of As(V) (Y00: pH 2–3, t 1/2 = 3.12 min; Y05: pH 2–6, t 1/2 = 2.12 min and Y10: pH 2–10, t 1/2 = 1.12 min). The results point to incorporation of Y3+ in the crystal lattice of magnetite, inducing nanorod spinel structure formation with significant changes in sorption properties important for the removal of inorganic arsenic from waters.",
publisher = "IOP Publishing",
journal = "Nanotechnology",
title = "Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species",
volume = "30",
number = "47",
pages = "475702",
doi = "10.1088/1361-6528/ab3ca2"
}

Dojčinović, B., Jančar, B., Bessais, L., Kremenović, A., Jović-Jovičić, N., Banković, P., Stanković, D., Ognjanović, M.,& Antić, B.. (2019). Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species. in Nanotechnology
IOP Publishing., 30(47), 475702.
https://doi.org/10.1088/1361-6528/ab3ca2

Dojčinović B, Jančar B, Bessais L, Kremenović A, Jović-Jovičić N, Banković P, Stanković D, Ognjanović M, Antić B. Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species. in Nanotechnology. 2019;30(47):475702.
doi:10.1088/1361-6528/ab3ca2 .

Dojčinović, Biljana, Jančar, Boštjan, Bessais, Lotfi, Kremenović, Aleksandar, Jović-Jovičić, Nataša, Banković, Predrag, Stanković, Dalibor, Ognjanović, Miloš, Antić, Bratislav, "Differently shaped nanocrystalline (Fe, Y)3O4 and its adsorption efficiency toward inorganic arsenic species" in Nanotechnology, 30, no. 47 (2019):475702,
https://doi.org/10.1088/1361-6528/ab3ca2 . .

TY  - CONF
AU  - Tančić, Pavle
AU  - Kremenović, Aleksandar
AU  - Vulić, Predrag
PY  - 2016
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6037
AB  - Састав проучаваног макроскопски зонарног грандита са локалитета Мека Преседла (Копаоник, Србија) је приказана.
AB  - Composition of the studied macroscopically zoned grandite from the Meka Presedla locality (Kopaonik Mt., Serbia) was shown.
PB  - Belgrade : Serbian Crystallographic Society
C3  - Изводи радова - XXIII Конференција Српског кристалографског друштва / Abstracts - 23rd Conference of the Serbian Crystallographic Society
T1  - Структурна десиметризација грандита са Меке Преседле (Копаоник, Србија)
T1  - Structural dissymetrization of grandite from Meka Presedla (Kopaonik Mt., Serbia)
SP  - 70
EP  - 71
UR  - https://hdl.handle.net/21.15107/rcub_cer_6037
ER  - 

@conference{
author = "Tančić, Pavle and Kremenović, Aleksandar and Vulić, Predrag",
year = "2016",
abstract = "Састав проучаваног макроскопски зонарног грандита са локалитета Мека Преседла (Копаоник, Србија) је приказана., Composition of the studied macroscopically zoned grandite from the Meka Presedla locality (Kopaonik Mt., Serbia) was shown.",
publisher = "Belgrade : Serbian Crystallographic Society",
journal = "Изводи радова - XXIII Конференција Српског кристалографског друштва / Abstracts - 23rd Conference of the Serbian Crystallographic Society",
title = "Структурна десиметризација грандита са Меке Преседле (Копаоник, Србија), Structural dissymetrization of grandite from Meka Presedla (Kopaonik Mt., Serbia)",
pages = "70-71",
url = "https://hdl.handle.net/21.15107/rcub_cer_6037"
}

Tančić, P., Kremenović, A.,& Vulić, P.. (2016). Структурна десиметризација грандита са Меке Преседле (Копаоник, Србија). in Изводи радова - XXIII Конференција Српског кристалографског друштва / Abstracts - 23rd Conference of the Serbian Crystallographic Society
Belgrade : Serbian Crystallographic Society., 70-71.
https://hdl.handle.net/21.15107/rcub_cer_6037

Tančić P, Kremenović A, Vulić P. Структурна десиметризација грандита са Меке Преседле (Копаоник, Србија). in Изводи радова - XXIII Конференција Српског кристалографског друштва / Abstracts - 23rd Conference of the Serbian Crystallographic Society. 2016;:70-71.
https://hdl.handle.net/21.15107/rcub_cer_6037 .

Tančić, Pavle, Kremenović, Aleksandar, Vulić, Predrag, "Структурна десиметризација грандита са Меке Преседле (Копаоник, Србија)" in Изводи радова - XXIII Конференција Српског кристалографског друштва / Abstracts - 23rd Conference of the Serbian Crystallographic Society (2016):70-71,
https://hdl.handle.net/21.15107/rcub_cer_6037 .

TY  - JOUR
AU  - Antić, Bratislav
AU  - Kremenovic, A.
AU  - Draganic, I.
AU  - Colomban, Ph.
AU  - Vasiljević-Radović, Dana
AU  - Blanusa, J.
AU  - Tadić, Marin
AU  - Mitrić, Miodrag
PY  - 2009
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/533
AB  - We report the results of ion irradiation influence on rare earth sesquioxides structure, which are materials of practical importance as a radiation resistant ceramics in nuclear applications. Y2O3, Gd2O3 and Er2O3 sesquioxides in the pellet form were irradiated by oxygen ions (O2+) beam with the energy of 30 keV and implantation fluence of 5 x 10(20) m (2). Samples are characterized by Grazing Incidence X-ray Diffraction (GIXRD), Raman spectroscopy and atomic force microscopy (AFM). By GIXRD it was found partial transformation from cubic
PB  - Elsevier
T2  - Applied Surface Science
T1  - Effects of O2+ ions beam irradiation on crystal structure of rare earth sesquioxides
VL  - 255
IS  - 17
SP  - 7601
EP  - 7604
DO  - 10.1016/j.apsusc.2009.04.035
ER  - 

@article{
author = "Antić, Bratislav and Kremenovic, A. and Draganic, I. and Colomban, Ph. and Vasiljević-Radović, Dana and Blanusa, J. and Tadić, Marin and Mitrić, Miodrag",
year = "2009",
abstract = "We report the results of ion irradiation influence on rare earth sesquioxides structure, which are materials of practical importance as a radiation resistant ceramics in nuclear applications. Y2O3, Gd2O3 and Er2O3 sesquioxides in the pellet form were irradiated by oxygen ions (O2+) beam with the energy of 30 keV and implantation fluence of 5 x 10(20) m (2). Samples are characterized by Grazing Incidence X-ray Diffraction (GIXRD), Raman spectroscopy and atomic force microscopy (AFM). By GIXRD it was found partial transformation from cubic",
publisher = "Elsevier",
journal = "Applied Surface Science",
title = "Effects of O2+ ions beam irradiation on crystal structure of rare earth sesquioxides",
volume = "255",
number = "17",
pages = "7601-7604",
doi = "10.1016/j.apsusc.2009.04.035"
}

Antić, B., Kremenovic, A., Draganic, I., Colomban, Ph., Vasiljević-Radović, D., Blanusa, J., Tadić, M.,& Mitrić, M.. (2009). Effects of O2+ ions beam irradiation on crystal structure of rare earth sesquioxides. in Applied Surface Science
Elsevier., 255(17), 7601-7604.
https://doi.org/10.1016/j.apsusc.2009.04.035

Antić B, Kremenovic A, Draganic I, Colomban P, Vasiljević-Radović D, Blanusa J, Tadić M, Mitrić M. Effects of O2+ ions beam irradiation on crystal structure of rare earth sesquioxides. in Applied Surface Science. 2009;255(17):7601-7604.
doi:10.1016/j.apsusc.2009.04.035 .

Antić, Bratislav, Kremenovic, A., Draganic, I., Colomban, Ph., Vasiljević-Radović, Dana, Blanusa, J., Tadić, Marin, Mitrić, Miodrag, "Effects of O2+ ions beam irradiation on crystal structure of rare earth sesquioxides" in Applied Surface Science, 255, no. 17 (2009):7601-7604,
https://doi.org/10.1016/j.apsusc.2009.04.035 . .

TY  - CONF
AU  - Nedić, B.
AU  - Dondur, Vera
AU  - Kremenović, Aleksandar
AU  - Dimitrijević, R.
AU  - Antić, Bratislav
AU  - Blanuša, J.
AU  - Vasiljević-Radović, Dana
AU  - Stoiljković, Milovan
PY  - 2007
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/353
AB  - Yb3+-doped Ba and Sr diphyllosilicates (hexacelsians) have been synthesized using the Na form of LTA zeolite by ion-exchange procedure and thermal treatment. The crystal structures of both doped samples are refined and described in this article. The results of Rietveld refinements clearly indicate that Yb3+ ions are incorporated into the hexacelsians structure. AFM photomicrographs show round-shaped particles with the size of few microns. The magnetization measurements were done within the 2-300 K temperature range, revealing an enhancement of magnetization with temperature that is not in accordance with simple paramagnetic behavior.
PB  - Maik Nauka/Interperiodica/Springer, New York
C3  - Russian Journal of Physical Chemistry A
T1  - Yb3+ doped dyphillosilicates prepared by thermally induced phase transformation of zeolites
VL  - 81
IS  - 9
SP  - 1413
EP  - 1417
DO  - 10.1134/S0036024407090129
ER  - 

@conference{
author = "Nedić, B. and Dondur, Vera and Kremenović, Aleksandar and Dimitrijević, R. and Antić, Bratislav and Blanuša, J. and Vasiljević-Radović, Dana and Stoiljković, Milovan",
year = "2007",
abstract = "Yb3+-doped Ba and Sr diphyllosilicates (hexacelsians) have been synthesized using the Na form of LTA zeolite by ion-exchange procedure and thermal treatment. The crystal structures of both doped samples are refined and described in this article. The results of Rietveld refinements clearly indicate that Yb3+ ions are incorporated into the hexacelsians structure. AFM photomicrographs show round-shaped particles with the size of few microns. The magnetization measurements were done within the 2-300 K temperature range, revealing an enhancement of magnetization with temperature that is not in accordance with simple paramagnetic behavior.",
publisher = "Maik Nauka/Interperiodica/Springer, New York",
journal = "Russian Journal of Physical Chemistry A",
title = "Yb3+ doped dyphillosilicates prepared by thermally induced phase transformation of zeolites",
volume = "81",
number = "9",
pages = "1413-1417",
doi = "10.1134/S0036024407090129"
}

Nedić, B., Dondur, V., Kremenović, A., Dimitrijević, R., Antić, B., Blanuša, J., Vasiljević-Radović, D.,& Stoiljković, M.. (2007). Yb3+ doped dyphillosilicates prepared by thermally induced phase transformation of zeolites. in Russian Journal of Physical Chemistry A
Maik Nauka/Interperiodica/Springer, New York., 81(9), 1413-1417.
https://doi.org/10.1134/S0036024407090129

Nedić B, Dondur V, Kremenović A, Dimitrijević R, Antić B, Blanuša J, Vasiljević-Radović D, Stoiljković M. Yb3+ doped dyphillosilicates prepared by thermally induced phase transformation of zeolites. in Russian Journal of Physical Chemistry A. 2007;81(9):1413-1417.
doi:10.1134/S0036024407090129 .

Nedić, B., Dondur, Vera, Kremenović, Aleksandar, Dimitrijević, R., Antić, Bratislav, Blanuša, J., Vasiljević-Radović, Dana, Stoiljković, Milovan, "Yb3+ doped dyphillosilicates prepared by thermally induced phase transformation of zeolites" in Russian Journal of Physical Chemistry A, 81, no. 9 (2007):1413-1417,
https://doi.org/10.1134/S0036024407090129 . .