МЕЖДУНАРОДНЫЙ ИНСТИТУТ
ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ
Международный Университет Фундаментального Обучения
Международный Парламент Безопасности и Мира
INTERNATIONAL PATENT
МЕЖДУНАРОДНЫЙ ПАТЕНТ
НА ОТКРЫТИЕ № / 01.001, 01.013
СУЩНОСТЬ ЯВЛЕНИЯ НАНОПРОЦЕССА МАССОПЕРЕНОСА
НА ГРАНИЦЕ РАЗДЕЛА СПЛОШНЫХ СРЕД
Патентообладатель и автор: Симоненко Зинаида Григорьевна (RU)
Гранд-Доктор Философии в области физики и математики
Полный Профессор Оксфорда
Заявка № 093 / 01.001,01.013
Приоритет открытия 30 ноября 2011года
Зарегистрирован в Международном Институте Интеллектуальной
Собственности (МИИС) при МУФО и Международном
Парламенте Безопасности и Мира
29 ноября 2015 года
Срок действия патента истекает 31 декабря 2035года
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INTERNATIONAL PATENT
INTERNATIONAL INSTITUTE
OF INTELLECTUAL PROPERTY
International University of Fundamental Studies
International Parliament for Safety and Peace
МЕЖДУНАРОДНЫЙ ИНСТИТУТ
ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ
Международный Университет Фундаментального Обучения
Международный Парламент Безопасности и Мира
INTERNATIONAL INSTITUTE
OF INTELLECTUAL PROPERTY
International University of Fundamental Studies
International Parliament for Safety and Peace
INTERNATIONAL INSTITUTE
OF INTELLECTUAL PROPERTY
International University of Fundamental Studies
International Parliament for Safety and Peace
INTERNATIONAL PATENT
FOR INVENTION № / 01 .001, 01.013
SUMMARY OF MASS TRANSFER NANOPROCESSES
ON THE BOUNDARY OF CONTINUOUS MEDIA
PATENT
Patenter and :Author: Prof. Simonenko Zinaida Grigorjevna (RU)
Grand-Doctor of Philosophy in Physics and Mathematics
Full Professor of Oxford
Application № / 01 .001, 01.013
Invention Priority on 30 November, 2011
Registered at the International Institute of Intellectual Property under IUFS
and the International Parliament for Safety and Peace
29 November 2015
Validity of the International Patent expires on 31 December 2015
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Author of the discovery: Prof. Simonenko Zinaida Grigorjevna(RU), Grand-Doctor of Philosophy in Physics and Mathematics, Full Professor of Oxford
Date and place of birth: May 4, 1950, г. Sochi
From 1968 to 1974 she studied at the Leningrad Institute of Precision Mechanics and Optics.From 1980 to 1983 she studied in SZPI graduate with a degree in “Physical Chemistry”.The ITMO received her PhD in 2000 on the topic “Methods and instruments for the study of the mass transfer of water systems with an interface.” In the period from 2003 to 2005.she studied at the St. Petersburg ITMO doctorate. . Defended in 2014 at IHAC IUFS thesis on “Methodology of physical and mathematical modeling nanoprocesses mass transfer of continuous media” on competition Grand Doctor of Philosophy in Physics and Mathematics. For outstanding contribution to science in 2015 ZG Symonenko was awarded the rank of full professor at Oxford from Oxford Educational Network (OEN). She was also awarded a gold medal from the International Parliament for Safety and Peace (IPSP) and a personal certificate in the nomination «BEST WORLD SCIENTIS OF THE YEAR-2015» from (MUFO OEN)
INTERNATIONAL PATENT FOR INVENTION № 01.001,01.013 SUMMARY OF MASS
TRANSFER NANOPROCESSES ON THE BOUNDARY OF CONTINUOUS MEDIA
- Introduction
The phenomenon of nontranslational mass transfer (known as diffusion) is linked with a wide range of theoretical and applied physics problems. These particular phenomena play a major role in physics of liquids, theory of solutions, and molecular biophysics. The study of rates of the mass transfer processes is of great interest for the practices of process design (e.g. the coolant in a reactor).
However, there had existed no methods or devices that would allow one to obtain the results in the form of the coefficient of diffusion, which is the main physicochemical parameter of a continuous medium.
Due to this, there was no means to describe the process itself mathematically, and the only existing approach, that of Obreimov (1830’s), did not provide a means of obtaining a rigorous mathematical description of the essence of behavior of the process of diffusion.
However, the gradient approach proposed by the author has provided a way to mathematically describe this process, which is analogous to the process of transferring ions through a cellular membrane divider. The experimental results received from this are of substantial novelty, and the project is a pilot one
- Priority information
Priority of discovery: 30 November 2011
The key findings of the research have been approbated at the international congresses:
III World Scientific Congress, Saint Petersburg, Russian Federation, 09/29/2011-09/30/2011
IV World Scientific Congress, Saint Petersburg, Russian Federation, 11/22/2012-11/23/2012
VI World Scientific Congress, Saint Petersburg, Russian Federation, 11/11/2014-11/12/2014
VII World Scientific Congress, Saint Petersburg, Russian Federation, 11/26/2015-11/27/2015
3.The sammary of invention
The resulting discovery relies on the systemic approach to the specified problem, which is based on theoretical and experimental methods of research.
Theoretical methods include the systems analysis methods, theory of solution construction, methods of physical chemistry, theory of inventive problem solving and patent research, laser methods of nondestructive testing, methods of polarization interferometry and ellipsometry, theory of digital signal processing (DSP), theory of experiment, theoretical bases of metrology of instrument engineering, the mathematical apparatus of linear algebra which includes the differential and integral calculus, basic numerical methods, Lamé transformations, the Riemannian equation, theory and methods of CAD including the method of modular design, theory of document science, programming theory, computer and simulation modeling, as well as the basics of information technology.
In the course of theoretical research there has been described a total of four simulated models of the implementation of the nano-process of mass transfer in the interface between two mediums; four equations of mathematical optics for these models have also been derived.
Experimental research has been conducted with the use of the method proposed by the author, as well as a laser ellipsometer for determining the parameters of the specified nanoprocess, also implemented by the author based on a developmental prototype.
The combination of methods of polarization interferometry and null ellipsometry provides a high accuracy of the conducted measurements, due to which the high-accuracy measurements conducted by the author, superior to the existing approaches by over tens of times, have been able to show that the parameter of mass transfer is in fact a nano-parameter which describes the distinguishing characteristics of the physicochemical process of diffusion.
Observing the graphs of the velocity changes of the studied process and the measured parameter, it is possible to conduct continuous and discrete control of the rate of the process of mass transfer in a binary medium. From the nature of the observed graph one can evaluate the rate of the process, the level of destructuring of the continuous binary medium and the general picture of the phenomenology of nontranslational mass transfer of the components of liquid binary systems with a boundary line in real time. Moreover, with the use of the proposed approach it became possible to understand the nature of the physicaland chemistry of solutions of weak concentration, and in doing so, to substantiate the homeopathy of moderate and high dilution solutions.
The validity and authenticity of the scientific propositions, conclusions and recommendations are substantiated and are ensured by the rigidity of the description of the problem and the accuracy of the mathematical justification of the conducted research, as well as the systemic approach to the solution of the given problems, metrological substantiation and the correspondence of the results of the natural and computational experiments, as well as the approbation of the obtained data at scientific and technical conferences, symposiums and world congresses.
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