Mechanochemical approach for non-enzymatic sensing materials
2022
Преузимање 🢃
Аутори
Mudrinić, TihanaMilovanović, Biljana
Petrović, Srđan
Pavlović, Stefan
Banković, Predrag
Milutinović Nikolić, Aleksandra
Конференцијски прилог (Објављена верзија)
Метаподаци
Приказ свих података о документуАпстракт
Recently the focus of electrochemical glucose sensing is on the fabrication of enzyme-free electrodes based on non-precious transition metal oxides, especially cobalt oxide [1]. To our best knowledge, these materials were primarily prepared by conventional methods using solutions, while the solvent-free mechanochemical approach was scarcely reported. Therefore, in this work Co3O4 supported on alumina (Co3O4/Al2O3) were prepared by ball milling using different milling times (0.5, 1, and 2 h) and Co3O4 contents (4, 8, and 16 wt. %). Ball to powder ratio was 30:1 and the rotation speed was 300 rpm. The electrodes based on the synthesized material were prepared in the form of a carbon paste electrodes (CP-Co3O4/Al2O3). The particle size distribution, phase, and chemical composition of the obtained materials were determined using LDPSA, XRPD, and XRF, respectively. The electrochemical performance of the CP-Co3O4/A12O3 electrode was tested in an alkaline solution containing glucose using cyc...lovoltammetry (CV) and chronoamperometry (ChA). CV revealed that milling time affected the electrochemical response. The highest current response was obtained with material milled for 1 h. Both ChA and CV confirmed that the electrochemical performance was further improved by increasing cobalt content. The CP electrode-based mechanochemically prepared samples showed enhanced performance in comparison to hand mixed Co3O4 and alumina. The beneficial effect of ball milling was attributed to the high dispersion of cobalt oxides over alumina even for large cobalt loadings without agglomeration. The obtained experimental results proved that the solvent-free mechanochemical approach is a promising synthetic route for obtaining green and sustainable glucose-sensing material for the fourth generation.
Кључне речи:
sensing / electrodes / non-precious transition metal oxides / cobalt oxide / electrochemistry / mechanochemistry / glucose-sensing materialsИзвор:
Book of abstracts - 10th International Conference on Mechanochemistry and Mechanical Alloying, 2022Издавач:
- Calgary, Italy : University of Cagliari
- COST Action CA18112
Финансирање / пројекти:
- Министарство науке, технолошког развоја и иновација Републике Србије, институционално финансирање - 200026 (Универзитет у Београду, Институт за хемију, технологију и металургију - ИХТМ) (RS-MESTD-inst-2020-200026)
- COST Action CA18112 - Mechanochemistry for Sustainable Industry (Mech@SustInd)
Институција/група
IHTMTY - CONF AU - Mudrinić, Tihana AU - Milovanović, Biljana AU - Petrović, Srđan AU - Pavlović, Stefan AU - Banković, Predrag AU - Milutinović Nikolić, Aleksandra PY - 2022 UR - https://cer.ihtm.bg.ac.rs/handle/123456789/5305 AB - Recently the focus of electrochemical glucose sensing is on the fabrication of enzyme-free electrodes based on non-precious transition metal oxides, especially cobalt oxide [1]. To our best knowledge, these materials were primarily prepared by conventional methods using solutions, while the solvent-free mechanochemical approach was scarcely reported. Therefore, in this work Co3O4 supported on alumina (Co3O4/Al2O3) were prepared by ball milling using different milling times (0.5, 1, and 2 h) and Co3O4 contents (4, 8, and 16 wt. %). Ball to powder ratio was 30:1 and the rotation speed was 300 rpm. The electrodes based on the synthesized material were prepared in the form of a carbon paste electrodes (CP-Co3O4/Al2O3). The particle size distribution, phase, and chemical composition of the obtained materials were determined using LDPSA, XRPD, and XRF, respectively. The electrochemical performance of the CP-Co3O4/A12O3 electrode was tested in an alkaline solution containing glucose using cyclovoltammetry (CV) and chronoamperometry (ChA). CV revealed that milling time affected the electrochemical response. The highest current response was obtained with material milled for 1 h. Both ChA and CV confirmed that the electrochemical performance was further improved by increasing cobalt content. The CP electrode-based mechanochemically prepared samples showed enhanced performance in comparison to hand mixed Co3O4 and alumina. The beneficial effect of ball milling was attributed to the high dispersion of cobalt oxides over alumina even for large cobalt loadings without agglomeration. The obtained experimental results proved that the solvent-free mechanochemical approach is a promising synthetic route for obtaining green and sustainable glucose-sensing material for the fourth generation. PB - Calgary, Italy : University of Cagliari PB - COST Action CA18112 C3 - Book of abstracts - 10th International Conference on Mechanochemistry and Mechanical Alloying T1 - Mechanochemical approach for non-enzymatic sensing materials UR - https://hdl.handle.net/21.15107/rcub_cer_5305 ER -
@conference{ author = "Mudrinić, Tihana and Milovanović, Biljana and Petrović, Srđan and Pavlović, Stefan and Banković, Predrag and Milutinović Nikolić, Aleksandra", year = "2022", abstract = "Recently the focus of electrochemical glucose sensing is on the fabrication of enzyme-free electrodes based on non-precious transition metal oxides, especially cobalt oxide [1]. To our best knowledge, these materials were primarily prepared by conventional methods using solutions, while the solvent-free mechanochemical approach was scarcely reported. Therefore, in this work Co3O4 supported on alumina (Co3O4/Al2O3) were prepared by ball milling using different milling times (0.5, 1, and 2 h) and Co3O4 contents (4, 8, and 16 wt. %). Ball to powder ratio was 30:1 and the rotation speed was 300 rpm. The electrodes based on the synthesized material were prepared in the form of a carbon paste electrodes (CP-Co3O4/Al2O3). The particle size distribution, phase, and chemical composition of the obtained materials were determined using LDPSA, XRPD, and XRF, respectively. The electrochemical performance of the CP-Co3O4/A12O3 electrode was tested in an alkaline solution containing glucose using cyclovoltammetry (CV) and chronoamperometry (ChA). CV revealed that milling time affected the electrochemical response. The highest current response was obtained with material milled for 1 h. Both ChA and CV confirmed that the electrochemical performance was further improved by increasing cobalt content. The CP electrode-based mechanochemically prepared samples showed enhanced performance in comparison to hand mixed Co3O4 and alumina. The beneficial effect of ball milling was attributed to the high dispersion of cobalt oxides over alumina even for large cobalt loadings without agglomeration. The obtained experimental results proved that the solvent-free mechanochemical approach is a promising synthetic route for obtaining green and sustainable glucose-sensing material for the fourth generation.", publisher = "Calgary, Italy : University of Cagliari, COST Action CA18112", journal = "Book of abstracts - 10th International Conference on Mechanochemistry and Mechanical Alloying", title = "Mechanochemical approach for non-enzymatic sensing materials", url = "https://hdl.handle.net/21.15107/rcub_cer_5305" }
Mudrinić, T., Milovanović, B., Petrović, S., Pavlović, S., Banković, P.,& Milutinović Nikolić, A.. (2022). Mechanochemical approach for non-enzymatic sensing materials. in Book of abstracts - 10th International Conference on Mechanochemistry and Mechanical Alloying Calgary, Italy : University of Cagliari.. https://hdl.handle.net/21.15107/rcub_cer_5305
Mudrinić T, Milovanović B, Petrović S, Pavlović S, Banković P, Milutinović Nikolić A. Mechanochemical approach for non-enzymatic sensing materials. in Book of abstracts - 10th International Conference on Mechanochemistry and Mechanical Alloying. 2022;. https://hdl.handle.net/21.15107/rcub_cer_5305 .
Mudrinić, Tihana, Milovanović, Biljana, Petrović, Srđan, Pavlović, Stefan, Banković, Predrag, Milutinović Nikolić, Aleksandra, "Mechanochemical approach for non-enzymatic sensing materials" in Book of abstracts - 10th International Conference on Mechanochemistry and Mechanical Alloying (2022), https://hdl.handle.net/21.15107/rcub_cer_5305 .