Thermal parameters defined with graph theory approach in synthetized diamonds
2022
Аутори
Mitić, Vojislav V.Randjelović, Branislav M.
Ribar, Srđan
Čebela, Maria
Mohr, Markus
Vlahović, Branislav
Fecht, Hans J.
Чланак у часопису (Објављена верзија)
Метаподаци
Приказ свих података о документуАпстракт
The Nanocrystaline diamonds are very important biomedical material with variety of applications. The experimental procedures and results have been done in the Institute of Functional Nanosystems at the University Ulm, Germany. There is an existing biocompatibility of the diamond layers, selectively improved by biomimetic 3-D patterns structuring. Based on that, we have been inspired to apply the graph theory approach in analysing and defining the physical parameters within the structure of materials structure samples. Instead the parameters values, characteristic at the samples surface, we penetrate the graphs deeply in the bulk structure. These values could be only, with some probability, distributed through the micro-structure what defines not enough precious parameters values between the micro-structure constituents, grains and pores. So, we originally applied the graph theory to get defined the physical parameters at the grains and pores levels. This novelty, in our paper, we appli...ed for thermophysical parameters, like thermoconductiviy. By graph approach we open new frontiers in controlling and defining the processes at micro-structure relations. In this way, we can easily predict and design the structure with proposed parameters.
Кључне речи:
thermal parameters / synthetized diamonds / nanocrystallinity / graph theory / biomimetics / biomaterialsИзвор:
Thermal Science, 2022, 26, 3, 2177-2186Издавач:
- Univerzitet u Beogradu - Institut za nuklearne nauke Vinča, Beograd
DOI: 10.2298/TSCI210422284M
ISSN: 0354-9836
WoS: 000805859400013
Scopus: 2-s2.0-85131439852
Колекције
Институција/група
Mašinski fakultetTY - JOUR AU - Mitić, Vojislav V. AU - Randjelović, Branislav M. AU - Ribar, Srđan AU - Čebela, Maria AU - Mohr, Markus AU - Vlahović, Branislav AU - Fecht, Hans J. PY - 2022 UR - https://machinery.mas.bg.ac.rs/handle/123456789/3743 AB - The Nanocrystaline diamonds are very important biomedical material with variety of applications. The experimental procedures and results have been done in the Institute of Functional Nanosystems at the University Ulm, Germany. There is an existing biocompatibility of the diamond layers, selectively improved by biomimetic 3-D patterns structuring. Based on that, we have been inspired to apply the graph theory approach in analysing and defining the physical parameters within the structure of materials structure samples. Instead the parameters values, characteristic at the samples surface, we penetrate the graphs deeply in the bulk structure. These values could be only, with some probability, distributed through the micro-structure what defines not enough precious parameters values between the micro-structure constituents, grains and pores. So, we originally applied the graph theory to get defined the physical parameters at the grains and pores levels. This novelty, in our paper, we applied for thermophysical parameters, like thermoconductiviy. By graph approach we open new frontiers in controlling and defining the processes at micro-structure relations. In this way, we can easily predict and design the structure with proposed parameters. PB - Univerzitet u Beogradu - Institut za nuklearne nauke Vinča, Beograd T2 - Thermal Science T1 - Thermal parameters defined with graph theory approach in synthetized diamonds EP - 2186 IS - 3 SP - 2177 VL - 26 DO - 10.2298/TSCI210422284M ER -
@article{ author = "Mitić, Vojislav V. and Randjelović, Branislav M. and Ribar, Srđan and Čebela, Maria and Mohr, Markus and Vlahović, Branislav and Fecht, Hans J.", year = "2022", abstract = "The Nanocrystaline diamonds are very important biomedical material with variety of applications. The experimental procedures and results have been done in the Institute of Functional Nanosystems at the University Ulm, Germany. There is an existing biocompatibility of the diamond layers, selectively improved by biomimetic 3-D patterns structuring. Based on that, we have been inspired to apply the graph theory approach in analysing and defining the physical parameters within the structure of materials structure samples. Instead the parameters values, characteristic at the samples surface, we penetrate the graphs deeply in the bulk structure. These values could be only, with some probability, distributed through the micro-structure what defines not enough precious parameters values between the micro-structure constituents, grains and pores. So, we originally applied the graph theory to get defined the physical parameters at the grains and pores levels. This novelty, in our paper, we applied for thermophysical parameters, like thermoconductiviy. By graph approach we open new frontiers in controlling and defining the processes at micro-structure relations. In this way, we can easily predict and design the structure with proposed parameters.", publisher = "Univerzitet u Beogradu - Institut za nuklearne nauke Vinča, Beograd", journal = "Thermal Science", title = "Thermal parameters defined with graph theory approach in synthetized diamonds", pages = "2186-2177", number = "3", volume = "26", doi = "10.2298/TSCI210422284M" }
Mitić, V. V., Randjelović, B. M., Ribar, S., Čebela, M., Mohr, M., Vlahović, B.,& Fecht, H. J.. (2022). Thermal parameters defined with graph theory approach in synthetized diamonds. in Thermal Science Univerzitet u Beogradu - Institut za nuklearne nauke Vinča, Beograd., 26(3), 2177-2186. https://doi.org/10.2298/TSCI210422284M
Mitić VV, Randjelović BM, Ribar S, Čebela M, Mohr M, Vlahović B, Fecht HJ. Thermal parameters defined with graph theory approach in synthetized diamonds. in Thermal Science. 2022;26(3):2177-2186. doi:10.2298/TSCI210422284M .
Mitić, Vojislav V., Randjelović, Branislav M., Ribar, Srđan, Čebela, Maria, Mohr, Markus, Vlahović, Branislav, Fecht, Hans J., "Thermal parameters defined with graph theory approach in synthetized diamonds" in Thermal Science, 26, no. 3 (2022):2177-2186, https://doi.org/10.2298/TSCI210422284M . .