Evaluation of Possible Isotopic Effects for Cavitational Carbon Nanoforms

Sergey Voropaev; Nikita Dushenko

doi:10.4028/www.scientific.net/NHC.28.117

Paper Titles

Study of Structure and Composition of Lead Sulfide Nanostructured Films Doped by Cadmium and Iodine Ions
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Study of Desorption Products under Laser Irradiation of the Surface of Organic Films
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The Relationship between Entropy and the Reliability Function in Application of Physical and Statistical Approach to Nanosystems
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Influence of Pressure on the Melting Temperature in the Contact of Expanded Nanofilms and Nanoparticles Used in Electronics
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Evaluation of Possible Isotopic Effects for Cavitational Carbon Nanoforms
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Chromium-Nickel Alloy for the Synthesis of Carbon Nanoparticles
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Features of the Conduction Mechanism through an Indium Antimonide Quantum Dot in the Analysis of Tunneling Current-Voltage Characteristics
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Analysis of Carbon Nanomaterials Produced by the Electric Arc Methods
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Study of Characteristics of HEMT-Transistors Based on AlGaN/GaN Heterostructure
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Evaluation of Possible Isotopic Effects for Cavitational Carbon Nanoforms

Abstract:

Possible processes of the carbon isotopes fraction under hydrodynamic caviation at carbon-containing liquids are considered. We have made corresponding experiments with benzene, toluene and ethanol to provide carbon nanoforms with different crystal structures. Specific bonding forces for metals and n-diamond are modeled using developed numerical method. The task is to identify the key parameters affecting the pairs force potentials of carbon atoms and consider the application of the results to microelectronics and natural processes.

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Periodical:

Nano Hybrids and Composites (Volume 28)

Pages:

117-122

DOI:

https://doi.org/10.4028/www.scientific.net/NHC.28.117

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Online since:

February 2020

Authors:

Sergey Voropaev*, Nikita Dushenko

Keywords:

Carbon, Cavitation, Diamond, Graphite, Isotope, Magnetism, Microelectronic

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* - Corresponding Author

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