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Fractal frontiers in microelectronic ceramic materials

Authorized Users Only
2019
Authors
Mitić, Vojislav V.
Lazović, Goran
Paunović, Vesna
Cvetković, Nenad
Jovanović, Dejan
Veljković, Sandra
Ranđelović, Branislav
Vlahović, Branislav
Article (Published version)
Metadata
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Abstract
The world's perennial need for energy and microelectronic miniaturization brings with it a broad set of technological and scientific challenges. Materials characterized by precise microstructural architectures based on fractal analysis and ranging in size down to nano scale represent an important avenue for finding novel solutions. Deep materials structure hierarchies of this type open new possibilities in capacity according to the Heywang model, especially when extended by a fractals approach and intergranular relationships supported and recognized by their fractal nature. These developments are opening new frontiers in microelectronics miniaturization. They build on early fractal applications that were used as tools in miniaturization research and also provided application perspectives for diverse energy technologies. In other words, fractals, as a crucial concept of modern theoretical-experimental physics and materials sciences, are tightly linked to higher integration processes and... microelectronics miniaturization. They also hold potential for meeting the energy exploitation challenge. In this research context, for the first time we experimentally and theoretically investigated the electrostatic field between the grains within fractal nature aspects. It is essentially a theoretical experiment based on samples of experimental microstructures imaged with SEM, as previously published in a number of other papers. We now take the research a step further by consolidating the experimental samples with respect to the predicted distribution of grains and pores within the sample mass. We make an original contribution by opening the frame of scale sizes with respect to the technical processes of consolidation. This lets us predict the constitutive elements of the microstructures – approximately equidistant grains and pores. In this paper we define in a practical manner the final target elements for experimental consolidation of real samples. It is the main bridge between a designed microstructure and related characteristics – for example, fractal dimensions and final properties of next-generation fractal microelectronics.

Keywords:
ceramic materials / electrostatic field / energy technologies / fractals / microelectronic miniaturization
Source:
Ceramics International, 2019, 45, 9679-9685
Publisher:
  • Elsevier
Funding / projects:
  • Directed synthesis, structure and properties of multifunctional materials (RS-172057)
Note:
  • Peer-reviewed manuscript: https://hdl.handle.net/21.15107/rcub_dais_4795
Related info:
  • Version of
    https://hdl.handle.net/21.15107/rcub_dais_4795

DOI: 10.1016/j.ceramint.2019.01.020

ISSN: 0272-8842

WoS: 000463688400049

Scopus: 2-s2.0-85059668665
[ Google Scholar ]
19
12
Handle
https://hdl.handle.net/21.15107/rcub_dais_5252
URI
http://www.sciencedirect.com/science/article/pii/S0272884219300227
https://dais.sanu.ac.rs/123456789/5252
Collections
  • ИТН САНУ - Општа колекција / ITS SASA - General collection
Institution/Community
Институт техничких наука САНУ / Institute of Technical Sciences of SASA
TY  - JOUR
AU  - Mitić, Vojislav V.
AU  - Lazović, Goran
AU  - Paunović, Vesna
AU  - Cvetković, Nenad
AU  - Jovanović, Dejan
AU  - Veljković, Sandra
AU  - Ranđelović, Branislav
AU  - Vlahović, Branislav
PY  - 2019
UR  - http://www.sciencedirect.com/science/article/pii/S0272884219300227
UR  - https://dais.sanu.ac.rs/123456789/5252
AB  - The world's perennial need for energy and microelectronic miniaturization brings with it a broad set of technological and scientific challenges. Materials characterized by precise microstructural architectures based on fractal analysis and ranging in size down to nano scale represent an important avenue for finding novel solutions. Deep materials structure hierarchies of this type open new possibilities in capacity according to the Heywang model, especially when extended by a fractals approach and intergranular relationships supported and recognized by their fractal nature. These developments are opening new frontiers in microelectronics miniaturization. They build on early fractal applications that were used as tools in miniaturization research and also provided application perspectives for diverse energy technologies. In other words, fractals, as a crucial concept of modern theoretical-experimental physics and materials sciences, are tightly linked to higher integration processes and microelectronics miniaturization. They also hold potential for meeting the energy exploitation challenge. In this research context, for the first time we experimentally and theoretically investigated the electrostatic field between the grains within fractal nature aspects. It is essentially a theoretical experiment based on samples of experimental microstructures imaged with SEM, as previously published in a number of other papers. We now take the research a step further by consolidating the experimental samples with respect to the predicted distribution of grains and pores within the sample mass. We make an original contribution by opening the frame of scale sizes with respect to the technical processes of consolidation. This lets us predict the constitutive elements of the microstructures – approximately equidistant grains and pores. In this paper we define in a practical manner the final target elements for experimental consolidation of real samples. It is the main bridge between a designed microstructure and related characteristics – for example, fractal dimensions and final properties of next-generation fractal microelectronics.
PB  - Elsevier
T2  - Ceramics International
T1  - Fractal frontiers in microelectronic ceramic materials
SP  - 9679
EP  - 9685
VL  - 45
DO  - 10.1016/j.ceramint.2019.01.020
UR  - https://hdl.handle.net/21.15107/rcub_dais_5252
ER  - 
@article{
author = "Mitić, Vojislav V. and Lazović, Goran and Paunović, Vesna and Cvetković, Nenad and Jovanović, Dejan and Veljković, Sandra and Ranđelović, Branislav and Vlahović, Branislav",
year = "2019",
abstract = "The world's perennial need for energy and microelectronic miniaturization brings with it a broad set of technological and scientific challenges. Materials characterized by precise microstructural architectures based on fractal analysis and ranging in size down to nano scale represent an important avenue for finding novel solutions. Deep materials structure hierarchies of this type open new possibilities in capacity according to the Heywang model, especially when extended by a fractals approach and intergranular relationships supported and recognized by their fractal nature. These developments are opening new frontiers in microelectronics miniaturization. They build on early fractal applications that were used as tools in miniaturization research and also provided application perspectives for diverse energy technologies. In other words, fractals, as a crucial concept of modern theoretical-experimental physics and materials sciences, are tightly linked to higher integration processes and microelectronics miniaturization. They also hold potential for meeting the energy exploitation challenge. In this research context, for the first time we experimentally and theoretically investigated the electrostatic field between the grains within fractal nature aspects. It is essentially a theoretical experiment based on samples of experimental microstructures imaged with SEM, as previously published in a number of other papers. We now take the research a step further by consolidating the experimental samples with respect to the predicted distribution of grains and pores within the sample mass. We make an original contribution by opening the frame of scale sizes with respect to the technical processes of consolidation. This lets us predict the constitutive elements of the microstructures – approximately equidistant grains and pores. In this paper we define in a practical manner the final target elements for experimental consolidation of real samples. It is the main bridge between a designed microstructure and related characteristics – for example, fractal dimensions and final properties of next-generation fractal microelectronics.",
publisher = "Elsevier",
journal = "Ceramics International",
title = "Fractal frontiers in microelectronic ceramic materials",
pages = "9679-9685",
volume = "45",
doi = "10.1016/j.ceramint.2019.01.020",
url = "https://hdl.handle.net/21.15107/rcub_dais_5252"
}
Mitić, V. V., Lazović, G., Paunović, V., Cvetković, N., Jovanović, D., Veljković, S., Ranđelović, B.,& Vlahović, B.. (2019). Fractal frontiers in microelectronic ceramic materials. in Ceramics International
Elsevier., 45, 9679-9685.
https://doi.org/10.1016/j.ceramint.2019.01.020
https://hdl.handle.net/21.15107/rcub_dais_5252
Mitić VV, Lazović G, Paunović V, Cvetković N, Jovanović D, Veljković S, Ranđelović B, Vlahović B. Fractal frontiers in microelectronic ceramic materials. in Ceramics International. 2019;45:9679-9685.
doi:10.1016/j.ceramint.2019.01.020
https://hdl.handle.net/21.15107/rcub_dais_5252 .
Mitić, Vojislav V., Lazović, Goran, Paunović, Vesna, Cvetković, Nenad, Jovanović, Dejan, Veljković, Sandra, Ranđelović, Branislav, Vlahović, Branislav, "Fractal frontiers in microelectronic ceramic materials" in Ceramics International, 45 (2019):9679-9685,
https://doi.org/10.1016/j.ceramint.2019.01.020 .,
https://hdl.handle.net/21.15107/rcub_dais_5252 .

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