Graph theory applied to microelectronics intergranular relations
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2021
Authors
Mitić, Vojislav V.Lazović, Goran

Ranđelović, Branislav

Paunović, Vesna
Radović, Ivana

Stajčić, Aleksandar

Vlahović, Branislav

Article (Published version)

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The focus of this study is on the control of layers between grains by applying graph theory. We performed modification of BaTiO3 nanoparticles with Y2O3. The results of capacitance change on submicron level are the part of the measured values on the bulk samples. The original idea is to develop the new approach to use graph theory for networking of electronic parameters between the neighboring grains in order to compare the values measured on the sample, and to present them through the edges in graph between corresponding vertices. Capacitance change with DC bias was measured on bulk samples, and the modified nanoparticles showed stability up to 90 V. After using graph theory with the different number of neighboring grains and on different voltages, it has been shown that capacitance change can be successfully calculated on the layers between grains. Original calculations presented as 1D cases were performed, confirming graph application as a tool with which measured bulk results can b...e downsized to an appropriate intergranular level, opening the new perspectives in the area of miniaturization and micropackaging.
Keywords:
computing technology / electronic signal / graph theory / intergranular capacitance changeSource:
Ferroelectrics, 2021, 570, 1, 145-152Publisher:
- Taylor & Francis Group
DOI: 10.1080/00150193.2020.1839265
ISSN: 0015-0193; 1563-5112
WoS: 000607319400014
Scopus: 2-s2.0-85097177409
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IHTMTY - JOUR AU - Mitić, Vojislav V. AU - Lazović, Goran AU - Ranđelović, Branislav AU - Paunović, Vesna AU - Radović, Ivana AU - Stajčić, Aleksandar AU - Vlahović, Branislav PY - 2021 UR - https://cer.ihtm.bg.ac.rs/handle/123456789/4837 AB - The focus of this study is on the control of layers between grains by applying graph theory. We performed modification of BaTiO3 nanoparticles with Y2O3. The results of capacitance change on submicron level are the part of the measured values on the bulk samples. The original idea is to develop the new approach to use graph theory for networking of electronic parameters between the neighboring grains in order to compare the values measured on the sample, and to present them through the edges in graph between corresponding vertices. Capacitance change with DC bias was measured on bulk samples, and the modified nanoparticles showed stability up to 90 V. After using graph theory with the different number of neighboring grains and on different voltages, it has been shown that capacitance change can be successfully calculated on the layers between grains. Original calculations presented as 1D cases were performed, confirming graph application as a tool with which measured bulk results can be downsized to an appropriate intergranular level, opening the new perspectives in the area of miniaturization and micropackaging. PB - Taylor & Francis Group T2 - Ferroelectrics T1 - Graph theory applied to microelectronics intergranular relations VL - 570 IS - 1 SP - 145 EP - 152 DO - 10.1080/00150193.2020.1839265 ER -
@article{ author = "Mitić, Vojislav V. and Lazović, Goran and Ranđelović, Branislav and Paunović, Vesna and Radović, Ivana and Stajčić, Aleksandar and Vlahović, Branislav", year = "2021", abstract = "The focus of this study is on the control of layers between grains by applying graph theory. We performed modification of BaTiO3 nanoparticles with Y2O3. The results of capacitance change on submicron level are the part of the measured values on the bulk samples. The original idea is to develop the new approach to use graph theory for networking of electronic parameters between the neighboring grains in order to compare the values measured on the sample, and to present them through the edges in graph between corresponding vertices. Capacitance change with DC bias was measured on bulk samples, and the modified nanoparticles showed stability up to 90 V. After using graph theory with the different number of neighboring grains and on different voltages, it has been shown that capacitance change can be successfully calculated on the layers between grains. Original calculations presented as 1D cases were performed, confirming graph application as a tool with which measured bulk results can be downsized to an appropriate intergranular level, opening the new perspectives in the area of miniaturization and micropackaging.", publisher = "Taylor & Francis Group", journal = "Ferroelectrics", title = "Graph theory applied to microelectronics intergranular relations", volume = "570", number = "1", pages = "145-152", doi = "10.1080/00150193.2020.1839265" }
Mitić, V. V., Lazović, G., Ranđelović, B., Paunović, V., Radović, I., Stajčić, A.,& Vlahović, B.. (2021). Graph theory applied to microelectronics intergranular relations. in Ferroelectrics Taylor & Francis Group., 570(1), 145-152. https://doi.org/10.1080/00150193.2020.1839265
Mitić VV, Lazović G, Ranđelović B, Paunović V, Radović I, Stajčić A, Vlahović B. Graph theory applied to microelectronics intergranular relations. in Ferroelectrics. 2021;570(1):145-152. doi:10.1080/00150193.2020.1839265 .
Mitić, Vojislav V., Lazović, Goran, Ranđelović, Branislav, Paunović, Vesna, Radović, Ivana, Stajčić, Aleksandar, Vlahović, Branislav, "Graph theory applied to microelectronics intergranular relations" in Ferroelectrics, 570, no. 1 (2021):145-152, https://doi.org/10.1080/00150193.2020.1839265 . .