TY  - CONF
AU  - Bošnjaković, Jovana
AU  - Bugarčić, Mladen
AU  - Milošević, Milena
AU  - Prlainović, Nevena
AU  - Salih, Rabab
AU  - Batinić, Petar
AU  - Popović, Ana
AU  - Đolić, Maja
PY  - 2022
UR  - https://ritnms.itnms.ac.rs/handle/123456789/938
AB  - The aim of this paper is to investigate the application of modified lignin-based adsorbent for
successful removal of dichromate ions and sodium diclofenac (DCF) from aqueous solutions by
adsorption. Modification of lignin-based adsorbent (LBA) was performed by inverse suspension
copolymerization with branched poly (ethylene-imine) using epichlorohydrin as a crosslinker. After
that, the functionalization of LBA was performed by chemical binding of amino modified nanoparticles
of manganese (IV) oxide, in order to improve the adsorption properties. Characterization of
LBA-MnO2 microspheres was performed using FT-IR spectrometer, Scanning electron microscopy,
BET/BJH analysis. The adsorption process was performed in a batch adsorption system. The results
were obtained with the help of kinetic and corresponding equilibrium adsorption isotherms. The
maximum adsorption capacity for the removal of Cr2O7
2- ions and DCF was obtained using the
Langmuir model and amounts to 88.4 mg g-1 and 52.8 mg g-1 at 45 °C, respectively. Adsorption
kinetics was described using a second-order pseudo model. Based on thermodynamic parameters, it
was concluded that the adsorption process is an endothermic and spontaneous. Based on the obtained
results, LBA-MnO2 material possess very good adsorption properties.
PB  - Bor : University of Belgrade, Technical Faculty in Bor
C3  - 29th International conference ecological truth and environmental research – EcoTER’22
T1  - Application of nano–MnO2 modified lignin – based adsorbent for removal of dichromate ions and diclofenac from water
EP  - 54
SP  - 49
ER  - 

@conference{
author = "Bošnjaković, Jovana and Bugarčić, Mladen and Milošević, Milena and Prlainović, Nevena and Salih, Rabab and Batinić, Petar and Popović, Ana and Đolić, Maja",
year = "2022",
abstract = "The aim of this paper is to investigate the application of modified lignin-based adsorbent for
successful removal of dichromate ions and sodium diclofenac (DCF) from aqueous solutions by
adsorption. Modification of lignin-based adsorbent (LBA) was performed by inverse suspension
copolymerization with branched poly (ethylene-imine) using epichlorohydrin as a crosslinker. After
that, the functionalization of LBA was performed by chemical binding of amino modified nanoparticles
of manganese (IV) oxide, in order to improve the adsorption properties. Characterization of
LBA-MnO2 microspheres was performed using FT-IR spectrometer, Scanning electron microscopy,
BET/BJH analysis. The adsorption process was performed in a batch adsorption system. The results
were obtained with the help of kinetic and corresponding equilibrium adsorption isotherms. The
maximum adsorption capacity for the removal of Cr2O7
2- ions and DCF was obtained using the
Langmuir model and amounts to 88.4 mg g-1 and 52.8 mg g-1 at 45 °C, respectively. Adsorption
kinetics was described using a second-order pseudo model. Based on thermodynamic parameters, it
was concluded that the adsorption process is an endothermic and spontaneous. Based on the obtained
results, LBA-MnO2 material possess very good adsorption properties.",
publisher = "Bor : University of Belgrade, Technical Faculty in Bor",
journal = "29th International conference ecological truth and environmental research – EcoTER’22",
title = "Application of nano–MnO2 modified lignin – based adsorbent for removal of dichromate ions and diclofenac from water",
pages = "54-49"
}

Bošnjaković, J., Bugarčić, M., Milošević, M., Prlainović, N., Salih, R., Batinić, P., Popović, A.,& Đolić, M.. (2022). Application of nano–MnO2 modified lignin – based adsorbent for removal of dichromate ions and diclofenac from water. in 29th International conference ecological truth and environmental research – EcoTER’22
Bor : University of Belgrade, Technical Faculty in Bor., 49-54.

Bošnjaković J, Bugarčić M, Milošević M, Prlainović N, Salih R, Batinić P, Popović A, Đolić M. Application of nano–MnO2 modified lignin – based adsorbent for removal of dichromate ions and diclofenac from water. in 29th International conference ecological truth and environmental research – EcoTER’22. 2022;:49-54..

Bošnjaković, Jovana, Bugarčić, Mladen, Milošević, Milena, Prlainović, Nevena, Salih, Rabab, Batinić, Petar, Popović, Ana, Đolić, Maja, "Application of nano–MnO2 modified lignin – based adsorbent for removal of dichromate ions and diclofenac from water" in 29th International conference ecological truth and environmental research – EcoTER’22 (2022):49-54.

TY  - CONF
AU  - Jovanović, Aleksandar
AU  - Bugarčić, Mladen
AU  - Čutović, Natalija
AU  - Bošnjaković, Jovana
AU  - Knežević, Nataša
AU  - Marinković, Aleksandar
PY  - 2022
UR  - https://ritnms.itnms.ac.rs/handle/123456789/675
AB  - Pollution of water presents one of the biggest problems of modern society. Pesticide
production, usage and release, as well as their persistence in the environment, have
detrimental effects on the aquatic and non-target species. Therefore, it is necessary to apply
treatment techniques in order to prevent these negative consequences. The processes used
so far do not have the necessary efficiency to optimally solve this problem. Hence, plenty
of advanced oxidation processes (AOPs) has been developed, among which photocatalysis
has stood out. Thus, photocatalytic degradation of fungicide thiophanate-methyl by using
recently synthesized catalyst Ag2O/TiO2 was considered. The effect of the various
parameters, such as catalyst amount, fungicide concentration, and also the distance of the
lamp from the photocatalytic reactor was studied. The obtained photocatalyst was examined
using Fourier transform infrared spectroscopy (FTIR), Scanning electron microscopy
(SEM), as well as Diffuse reflectance spectroscopy (DRS). Photocatalytic assays
employing Ag2O/TiO2 catalyst with the concentration of 0.065 g/l yielded the best results.
The degradation rate constant was measured as 0,040 min-1 by observing values of
absorbances from the UV spectrophotometer Shimadzu 1800. Under the optimal
conditions, the complete disappearance of 10 mg/l of fungicide occurred within 2 h by
using Ag2O/TiO2. However, the limitation of the applied process is reflected in the volume
of wastewater that can be treated, while making it economically viable. Obtained results
show that synthesized catalysts pose a great ability to effectively decompose thiophanatemethyl
under UV light.
PB  - Split : University of Split, Faculty of Chemistry and Technology
C3  - 3rd International convention of scientists, specialist employees and students on the topic of Environmental protection in the Republic of Croatia (3rd ZORH convention)
T1  - Modification of titanium-dioxide surface with silver(i)-oxide as a catalyst for photocatalytic degradation of fungicide
T1  - Modifikacija površine titanijum-dioksida srebro(i)-oksidom kao katalizatora za fotokatalitičku degradaciju fungicida
EP  - 26
SP  - 26
ER  - 

@conference{
author = "Jovanović, Aleksandar and Bugarčić, Mladen and Čutović, Natalija and Bošnjaković, Jovana and Knežević, Nataša and Marinković, Aleksandar",
year = "2022",
abstract = "Pollution of water presents one of the biggest problems of modern society. Pesticide
production, usage and release, as well as their persistence in the environment, have
detrimental effects on the aquatic and non-target species. Therefore, it is necessary to apply
treatment techniques in order to prevent these negative consequences. The processes used
so far do not have the necessary efficiency to optimally solve this problem. Hence, plenty
of advanced oxidation processes (AOPs) has been developed, among which photocatalysis
has stood out. Thus, photocatalytic degradation of fungicide thiophanate-methyl by using
recently synthesized catalyst Ag2O/TiO2 was considered. The effect of the various
parameters, such as catalyst amount, fungicide concentration, and also the distance of the
lamp from the photocatalytic reactor was studied. The obtained photocatalyst was examined
using Fourier transform infrared spectroscopy (FTIR), Scanning electron microscopy
(SEM), as well as Diffuse reflectance spectroscopy (DRS). Photocatalytic assays
employing Ag2O/TiO2 catalyst with the concentration of 0.065 g/l yielded the best results.
The degradation rate constant was measured as 0,040 min-1 by observing values of
absorbances from the UV spectrophotometer Shimadzu 1800. Under the optimal
conditions, the complete disappearance of 10 mg/l of fungicide occurred within 2 h by
using Ag2O/TiO2. However, the limitation of the applied process is reflected in the volume
of wastewater that can be treated, while making it economically viable. Obtained results
show that synthesized catalysts pose a great ability to effectively decompose thiophanatemethyl
under UV light.",
publisher = "Split : University of Split, Faculty of Chemistry and Technology",
journal = "3rd International convention of scientists, specialist employees and students on the topic of Environmental protection in the Republic of Croatia (3rd ZORH convention)",
title = "Modification of titanium-dioxide surface with silver(i)-oxide as a catalyst for photocatalytic degradation of fungicide, Modifikacija površine titanijum-dioksida srebro(i)-oksidom kao katalizatora za fotokatalitičku degradaciju fungicida",
pages = "26-26"
}

Jovanović, A., Bugarčić, M., Čutović, N., Bošnjaković, J., Knežević, N.,& Marinković, A.. (2022). Modification of titanium-dioxide surface with silver(i)-oxide as a catalyst for photocatalytic degradation of fungicide. in 3rd International convention of scientists, specialist employees and students on the topic of Environmental protection in the Republic of Croatia (3rd ZORH convention)
Split : University of Split, Faculty of Chemistry and Technology., 26-26.

Jovanović A, Bugarčić M, Čutović N, Bošnjaković J, Knežević N, Marinković A. Modification of titanium-dioxide surface with silver(i)-oxide as a catalyst for photocatalytic degradation of fungicide. in 3rd International convention of scientists, specialist employees and students on the topic of Environmental protection in the Republic of Croatia (3rd ZORH convention). 2022;:26-26..

Jovanović, Aleksandar, Bugarčić, Mladen, Čutović, Natalija, Bošnjaković, Jovana, Knežević, Nataša, Marinković, Aleksandar, "Modification of titanium-dioxide surface with silver(i)-oxide as a catalyst for photocatalytic degradation of fungicide" in 3rd International convention of scientists, specialist employees and students on the topic of Environmental protection in the Republic of Croatia (3rd ZORH convention) (2022):26-26.

TY  - CONF
AU  - Bošnjaković, Jovana
AU  - Knežević, Nataša
AU  - Manasijević, Srećko
AU  - Jovanović, Aleksandar
AU  - Bugarčić, Mladen
AU  - Marinković, Aleksandar
PY  - 2022
UR  - https://ritnms.itnms.ac.rs/handle/123456789/664
AB  - Due to the rapid development of industry and growth of population, water consumption is increased.
Beside this, releasing of xenobiotics, which represent significant pollutants into watercourse, like
heavy metal ions, pesticides, paints, and solvents, made this problem much bigger. Therefore, they
can enter into aquatic organisms directly from industrial plants or into human bodies indirectly
through agricultural products. New technologies, including photocatalytic decomposition, are
necessary for wastewater treatment as a highly efficient and low-cost process. Photocatalysis implies
the degradation of various types of harmful organic substances to simple molecules such as CO2, SO2,
ions, and water. The applied process has no detrimental effect on the environment and does not require
additional chemicals for precipitation of the products. In this work, photodegradation of the pesticide
difenoconazole (DFC) using a TiO2-based photocatalyst was examined using doubled wall
thermoregulated quartz reactor. As a replacement for UVC radiation, solar imitated Ultra Vitalux
(UV) lamp (300W) was used. Determination of DFC concentration was performed using a UV
method. Degradation kinetics follows pseudo-first order. After 120 minutes, the DFC was completely
degraded. Chemical oxygen demand (COD) also confirmed that successfully indicating that this
process can be used in treating of industrial wastewater.
PB  - Banja Luka : University in Banja Luka, Faculty of Technology
C3  - XIV CONFERENCE OF CHEMISTS, TECHNOLOGISTS AND ENVIRONMENTALISTS OF REPUBLIC OF SRPSKA
T1  - Photocatalytic decomposition of difenoconazole from wastewaters
EP  - 246
SP  - 242
ER  - 

@conference{
author = "Bošnjaković, Jovana and Knežević, Nataša and Manasijević, Srećko and Jovanović, Aleksandar and Bugarčić, Mladen and Marinković, Aleksandar",
year = "2022",
abstract = "Due to the rapid development of industry and growth of population, water consumption is increased.
Beside this, releasing of xenobiotics, which represent significant pollutants into watercourse, like
heavy metal ions, pesticides, paints, and solvents, made this problem much bigger. Therefore, they
can enter into aquatic organisms directly from industrial plants or into human bodies indirectly
through agricultural products. New technologies, including photocatalytic decomposition, are
necessary for wastewater treatment as a highly efficient and low-cost process. Photocatalysis implies
the degradation of various types of harmful organic substances to simple molecules such as CO2, SO2,
ions, and water. The applied process has no detrimental effect on the environment and does not require
additional chemicals for precipitation of the products. In this work, photodegradation of the pesticide
difenoconazole (DFC) using a TiO2-based photocatalyst was examined using doubled wall
thermoregulated quartz reactor. As a replacement for UVC radiation, solar imitated Ultra Vitalux
(UV) lamp (300W) was used. Determination of DFC concentration was performed using a UV
method. Degradation kinetics follows pseudo-first order. After 120 minutes, the DFC was completely
degraded. Chemical oxygen demand (COD) also confirmed that successfully indicating that this
process can be used in treating of industrial wastewater.",
publisher = "Banja Luka : University in Banja Luka, Faculty of Technology",
journal = "XIV CONFERENCE OF CHEMISTS, TECHNOLOGISTS AND ENVIRONMENTALISTS OF REPUBLIC OF SRPSKA",
title = "Photocatalytic decomposition of difenoconazole from wastewaters",
pages = "246-242"
}

Bošnjaković, J., Knežević, N., Manasijević, S., Jovanović, A., Bugarčić, M.,& Marinković, A.. (2022). Photocatalytic decomposition of difenoconazole from wastewaters. in XIV CONFERENCE OF CHEMISTS, TECHNOLOGISTS AND ENVIRONMENTALISTS OF REPUBLIC OF SRPSKA
Banja Luka : University in Banja Luka, Faculty of Technology., 242-246.

Bošnjaković J, Knežević N, Manasijević S, Jovanović A, Bugarčić M, Marinković A. Photocatalytic decomposition of difenoconazole from wastewaters. in XIV CONFERENCE OF CHEMISTS, TECHNOLOGISTS AND ENVIRONMENTALISTS OF REPUBLIC OF SRPSKA. 2022;:242-246..

Bošnjaković, Jovana, Knežević, Nataša, Manasijević, Srećko, Jovanović, Aleksandar, Bugarčić, Mladen, Marinković, Aleksandar, "Photocatalytic decomposition of difenoconazole from wastewaters" in XIV CONFERENCE OF CHEMISTS, TECHNOLOGISTS AND ENVIRONMENTALISTS OF REPUBLIC OF SRPSKA (2022):242-246.

TY  - CONF
AU  - Tomašević, Anđelka
AU  - Jovanović, Aleksandar
AU  - Bošnjaković, Jovana
AU  - Stevanović, Marija
AU  - Rusmirović, Jelena
AU  - Marinković, Aleksandar
PY  - 2021
UR  - https://ritnms.itnms.ac.rs/handle/123456789/662
AB  - With the development of the industry and growth of
the population, there is an increasing amount of waste,
which, due to inadequate treatment, pollutes water. The
group of the most dangerous pollutants present in water
includes heavy metals, such as As, Cd, Pb, Ni, Hg, Cr,
etc. [1]. Heavy metal ions are highly toxic and not biodegradable,
but are prone to accumulation in the body in
certain tissues and organs [2].
In recent years, natural materials, originating from
waste or renewable sources, have been increasingly
used as adsorbents in the removal of heavy metal ions
from water, due to their low cost, high prevalence and
beneficial impact on the environment [3]. Lignin, cellulose
and hemicellulose are the main polymers of wood
biomass [4]. Lignin is represented as a by-product in the
paper and pulp industry [5]. Chemical modification of
lignin was performed using acrylate derivatives (L-AC).
Modified lignin microspheres (LMS) were synthesized
by inverse suspension copolymerization using L-AC,
trimethylolpropane triacrylate (TMPTA) and methacryl
functionalized magnetite modified with MEMO silane
or with methacryloyl chloride (MACM1 or MACM2).
The procedure of inverse emulsion-suspension copolymerization
developed by Popović et al. [6] was used. In
a summary, disodium laureth sulfosuccinate (surfactant)
was stirred in water solution for 30 min at 80 °C. Afterwards,
TMPTA, L-MAC, MACM1 or MACM2 and the
initiator AIBN (1 wt. %) were added, followed by the
mixture of pore-forming solvents (tetradecanol and toluene),
stirred for 18 h at the same elevated temperature.
LMS microspheres were characterized by zero
charge point determination, FT-IR and SEM. The efficiency
of pollutants (chromium(VI) and arsenic(V)
ions) removal was analysed in terms of varying the
experimental conditions: the mass of adsorbent, the pH
of solution, the temperature of reaction and the contact
time. The best sorption was observed for the pH between
5.0 and 7.0. Synthesized bio-adsorbents showed
high efficiency, with capacities of 35.5 and 54.0 mg g-1
for the LMS adsorbents loaded with magnetite modified
using methacyl functionalized silane (LMS-1) or
methacryloyl chloride (LMS-2), respectively, obtained
according to Freundlich isothermal model. Adsorption
kinetics are described according to a pseudo-second
order model. Based on the obtained results, both adsorbents
showed excellent adsorption abilities.
Thermodynamic parameters, including the Gibbs
free energy (ΔGΘ), enthalpy (ΔHΘ) and entropy (ΔSΘ),
proved that adsorption is viable, spontaneous and endothermic
process (LMS-1) and exothermic process
(LMS-2) at temperatures between 25 and 45 °C.
PB  - Belgrade : Serbian Chemical Society
C3  - 21th European Meeting on Environmental Chemistry EMEC 21
T1  - Removal of Chromium(VI) and Arsenic(V) from Water Solution Using Modified Lignin Microspheres
EP  - 115
SP  - 115
ER  - 

@conference{
author = "Tomašević, Anđelka and Jovanović, Aleksandar and Bošnjaković, Jovana and Stevanović, Marija and Rusmirović, Jelena and Marinković, Aleksandar",
year = "2021",
abstract = "With the development of the industry and growth of
the population, there is an increasing amount of waste,
which, due to inadequate treatment, pollutes water. The
group of the most dangerous pollutants present in water
includes heavy metals, such as As, Cd, Pb, Ni, Hg, Cr,
etc. [1]. Heavy metal ions are highly toxic and not biodegradable,
but are prone to accumulation in the body in
certain tissues and organs [2].
In recent years, natural materials, originating from
waste or renewable sources, have been increasingly
used as adsorbents in the removal of heavy metal ions
from water, due to their low cost, high prevalence and
beneficial impact on the environment [3]. Lignin, cellulose
and hemicellulose are the main polymers of wood
biomass [4]. Lignin is represented as a by-product in the
paper and pulp industry [5]. Chemical modification of
lignin was performed using acrylate derivatives (L-AC).
Modified lignin microspheres (LMS) were synthesized
by inverse suspension copolymerization using L-AC,
trimethylolpropane triacrylate (TMPTA) and methacryl
functionalized magnetite modified with MEMO silane
or with methacryloyl chloride (MACM1 or MACM2).
The procedure of inverse emulsion-suspension copolymerization
developed by Popović et al. [6] was used. In
a summary, disodium laureth sulfosuccinate (surfactant)
was stirred in water solution for 30 min at 80 °C. Afterwards,
TMPTA, L-MAC, MACM1 or MACM2 and the
initiator AIBN (1 wt. %) were added, followed by the
mixture of pore-forming solvents (tetradecanol and toluene),
stirred for 18 h at the same elevated temperature.
LMS microspheres were characterized by zero
charge point determination, FT-IR and SEM. The efficiency
of pollutants (chromium(VI) and arsenic(V)
ions) removal was analysed in terms of varying the
experimental conditions: the mass of adsorbent, the pH
of solution, the temperature of reaction and the contact
time. The best sorption was observed for the pH between
5.0 and 7.0. Synthesized bio-adsorbents showed
high efficiency, with capacities of 35.5 and 54.0 mg g-1
for the LMS adsorbents loaded with magnetite modified
using methacyl functionalized silane (LMS-1) or
methacryloyl chloride (LMS-2), respectively, obtained
according to Freundlich isothermal model. Adsorption
kinetics are described according to a pseudo-second
order model. Based on the obtained results, both adsorbents
showed excellent adsorption abilities.
Thermodynamic parameters, including the Gibbs
free energy (ΔGΘ), enthalpy (ΔHΘ) and entropy (ΔSΘ),
proved that adsorption is viable, spontaneous and endothermic
process (LMS-1) and exothermic process
(LMS-2) at temperatures between 25 and 45 °C.",
publisher = "Belgrade : Serbian Chemical Society",
journal = "21th European Meeting on Environmental Chemistry EMEC 21",
title = "Removal of Chromium(VI) and Arsenic(V) from Water Solution Using Modified Lignin Microspheres",
pages = "115-115"
}

Tomašević, A., Jovanović, A., Bošnjaković, J., Stevanović, M., Rusmirović, J.,& Marinković, A.. (2021). Removal of Chromium(VI) and Arsenic(V) from Water Solution Using Modified Lignin Microspheres. in 21th European Meeting on Environmental Chemistry EMEC 21
Belgrade : Serbian Chemical Society., 115-115.

Tomašević A, Jovanović A, Bošnjaković J, Stevanović M, Rusmirović J, Marinković A. Removal of Chromium(VI) and Arsenic(V) from Water Solution Using Modified Lignin Microspheres. in 21th European Meeting on Environmental Chemistry EMEC 21. 2021;:115-115..

Tomašević, Anđelka, Jovanović, Aleksandar, Bošnjaković, Jovana, Stevanović, Marija, Rusmirović, Jelena, Marinković, Aleksandar, "Removal of Chromium(VI) and Arsenic(V) from Water Solution Using Modified Lignin Microspheres" in 21th European Meeting on Environmental Chemistry EMEC 21 (2021):115-115.