alexey anatolievich zakharenko · 2008 – additional education: certified interior designer...

CURRICULUM VITAE with PUBLICATION LIST and four REFERENCE LETTERS

Dr. A.A. Zakharenko (Diploma Engineer-Physicist & Diploma Programmer & Diploma Manager & Certified Interior Designer)

E-mail: [email protected] urls: https://www.researchgate.net/profile/Aleksey_Zakharenko and www.iizws.ru

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ALEKSEY ANATOLIEVICH ZAKHARENKO

International Institute of Zakharenko Waves (IIZWs)

Permanent and Mailing Address: 660014, ul. Chaikovskogo, 20-304, Krasnoyarsk, Siberia, Russia.

E-mail: [email protected]

url: https://www.researchgate.net/profile/Aleksey_Zakharenko url: www.iizws.ru

Gender: male;

Date of birth: 23.10.1974;

Birth-place: Minusinsk, Krasnoyarsk region, Russia;

Nationality: Russian;

Marital Status: single;

Address: 660014, Chaikovskogo-20, Krasnoyarsk, Siberia, Russia;

Working place and position: International Institute of Zakharenko Waves (IIZWs), Creator and

Researcher; Phone number: none; E-mail address: [email protected].

Education: 1998 – Diploma Engineer-Physicist (MSc), Physics: Material Science, Krasnoyarsk State University, Krasnoyarsk, Siberia,

Russia (with Professor Yu. V. Zakharov); Thesis: “Dynamical thresholds of stability and oscillations of elastic systems.”

2008 – Additional Education: Certified Interior Designer (Certificate, AutoCAD, 3ds max), Business School “Inoprof”,

Krasnoyarsk, Siberia, Russia.

2010 – my PhD carried out for the International Institute of Zakharenko Waves (IIZWs) was published as a book, see below

my book entitled “Propagation of Seven New SH-SAWs in Piezoelectromagnetics of Class 6 mm” Saarbruecken –

Krasnoyarsk, LAMBERT Academic Publishing GmbH & Co. KG, 2010, ISBN: 978-3-8433-6403-4.

2011 – Diploma Programmer (MSc, Russian red Diploma with excellence, second Diploma), Programming: Siberian State

Technological University, Krasnoyarsk, Siberia, Russia; Thesis: “Development of testing module for the discipline

“Algorithmic languages and programming” by means of MOODLE.” 2016 – Diploma Office Manager – Pomoshnik Rukovoditelya (MSc, Russian red Diploma with excellence, third Diploma),

Management: Moscow University for Industry and Finance “Synergy”, Moscow, Russia (Krasnoyarsk branch, Siberia,

Russia).

Sport Education:

1991 – First degree for the soccer game; sport organization: “Work reserves”, Chimkent, Kazakhstan (former Soviet Union) with registration number 386 from 08.07.1991 in the sport collective DUSSOR № 1 (“Detsko-Unosheskaya Sportivnaya Skola Olimpiiskogo Reserva” that is “Childish-Youthful Sport School of Olympic Reserve”). Study school: Middle School № 15 in Chimkent, Kazakhstan (former Soviet Union); the first trainer for the soccer game was Sharkov (he was a main trainer for soccer master team “Meliorator”, Chimkent, Kazakhstan) and the second trainer for the soccer game was who played for the Soviet Union National Soccer Team. 06.1990 – participations in sport forums: the third place in the School Spartakiada, Kazakhstan (former Soviet Union). 08.07.1991 – sport document (in Russian) with registration number 386 representing credit qualification book for sportsmen of first degree,

candidates of sport masters, USSR sport masters, and USSR sport masters of international level; Chimkent, Kazakhstan (former Soviet Union or USSR). Possible sport perspectives: to receive a trainer degree for the soccer game in order to create a soccer team consisting of only Nobel Prize Winners to play the soccer game.

Areas of Expertise:

The four-potential SH-SAWs and the other acoustic waves coupled with the electrical, magnetic,

gravitational, and cogravitational potentials; SH-SAWs in piezoelectromagnetics, piezoelectrics, and

piezomagnetics; magnetoelectric effect; computational and theoretical Physics; material science;

crystallography; layered structures; IC-MEMS structures; low temperature Physics; Quantum Physics;

Quantum Chemistry; Superfluidity; Superconductivity; high-energy Physics; plasmas; the nondispersive

Zakharenko waves in complex systems with dispersion relations; Physical Acoustics.

Research Experience:

01.2005 – present: The Creator of the International Institute of Zakharenko waves (IIZWs).

The International Institute of Zakharenko waves (IIZWs) was created for support of different Zakharenko waves, as well as

for monitoring the non-dispersive Zakharenko type waves in complex systems such as layered and quantum systems. Indeed,

mailto:[email protected]

https://www.researchgate.net/profile/Aleksey_Zakharenko

http://www.iizws.ru/

mailto:[email protected]




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any complex system, where dispersive waves (for example, dispersive Rayleigh and Bleustein-Gulyaev type waves as well

as Love and Lamb type waves) can propagate, is of a great interest for the Institute. There are currently twelve papers/works

relevant to the IIZWs. Also, there are several written and submitted papers as well as several papers in progress. The Institute studies different dispersive and non-dispersive waves both theoretically and experimentally, including different

applications of the waves for signal processing (filters, sensors, etc.) and the structural health monitoring. Therefore, any

interest from individuals and Institutions/Organizations is welcomed.

The International Institute of Zakharenko waves (IIZWs) possessively takes all the planets and smaller natural space bodies

in the space outside the Solar System space to develop both the IIZWs and the planets (economics, ecology, and population

including human-like persons currently leaving on Earth as well as for the future human-like generations) and to exclude any

sale of the planets and their surfaces by any human/other. Note that the single person, namely Professor Dennis Hope from

the United States possesses the planets in the Solar System (but Earth) who sells surfaces of the planets to individuals that is

horrible. This activity of the IIZWs is created due to impossibility to find a spot for the IIZWs on Earth: the IIZWs Creator

has asked the New Zealandian Embassy in Seoul, South Korea about a suitable spot for the IIZWs, because New Zealand is

very small-populated well-developed country on Earth. Note that on Earth there are no well-developed countries called New

Innovative Russia, New USA, or New Schwabia.

It is also thought that the IIZWs can evaluate ecological risks of presence of any man-made space bodies (satellites, space

ships, etc.) outside the Solar System to calculate charges for minimization of human presence in space outside the Solar

System. It is naturally expected that the charges will be increased with distance gone the space bodies in space towards any

direction from the Solar System space frames. Note that the intergalactic currency is used called “Black Holes” with its

derivatives: Black Hole, milli Black Hole, micro Black Hole, nano Black Hole, where one nano Black Hole is equal to one

Korean Won. It is thought that the Earth-Galaxy currency rate should be fixed for the first time. Also, the ecological risk

charge can be as high as one nano Black Hole (1 nBH) per kilometer. It is thought that the Black Hole intergalactic currency

can represent an additional dimension for economics of any planet in the Solar System and the other Star systems.

Also, it is obvious that the intergalactic financial fund called “Black Hole Financial Reserves” (BHFR) should be created for

investments of money in Black Holes to a planetary economics that can be readily done annually. Indeed, for the Earth

economics, they must be converted from Black Holes to the United States Dollars or European Euro: one Black Hole equals to one million of the United States Dollars, because intergalactic scales are much larger than interplanetary scales. It is also

obvious that one-Dollar fee is paid every year to the BHFR intergalactic financial fund from each Planet of over several

Pentallion Planets (over 1018 Planets) which can be readily found through our common Universe. Of course, if a planet

disagrees to pay the fee to the BHFR intergalactic financial fund, it should contact me as soon as possible. However,

anybody from a Planet can also pay the fees instead. Note that the one-Dollar fee is NOTHING even for an economics of

any country on the Earth, and it can be readily paid. Note that I paid 10 US-Dollars to the BHFR intergalactic financial fund

from the Earth for 2009 financial year, because I am an inhabitant of the Earth. The BHFR intergalactic financial fund

carries out financial investments into planetary and interplanetary projects: economics, ecology, transportation, leaving, etc.

A new planetary architectural style is represented for the International Institute of Zakharenko Waves (IIZWs) possessing

the all planets outside the Solar System. The new style is called the planetary stamp architectural style or Mitchell style. This

style should be looked like one square mile stamp on a surface of a planet or solid space body, see the figure below. That represents one Stamp-City for by about 100,000 inhabitants. It is as high as 99 leaving

floors plus 13 underground floors for car/other parking, shopping services, agricultural

areas, etc. Possible Stamp-Citie shapes are as follows: circle, ellipse, square,

rectangular, etc., as well as buildings-letters like “IIZWs”. Indeed, a collaborative work

of a Planetary Architect with a Creative Stamp Designer is required to realize a project

with the Mitchell style complex of buildings on a planetary surface. It is thought that

the Stamp-Cities can be first realized on our home planet Earth, probably, on areas near

natural deserts: North America (Nevada), South America (some areas), Africa (Sahara),

Europe (in Spain, Hungary, or Kalmykia Republic of Russia), Asia (in Saudi Arabia or

Mongolia), and Australia (some areas). It is apparent that modern solar and wind

electric power will be used in the Stamp-Cities. It is natural that individual stamps for

each Earth region or a planet can be readily used, for instance, in a holographic view to notarize any document for the IIZWs. It is blatant that NOTHING can be constructed

on surfaces of some planets called the gas giants, as well as on all stars including our Sun. That can mean that they cannot be

in possession of any person/institution, because the possession act can be never realized: a piece of paper will be notarized,

but not a planet/star ownership. Of course, something can be constructed above the surface of a planet called the gas giant or

above the star surface, in this case however any construction is recognized as a satellite of the planet/star resulting in the

possession of the satellite, but not of the planet/star.

11.2010 – 03.2011: a studentship during five months representing a second Diploma study (a second MSc

degree) for a qualification of programmer in the Siberian State Technological University (SSTU),

Krasnoyarsk, Siberia, Russia. o received a qualification in order to work as a programmer (a red Diploma with excellence);

o This Diploma work (MSc thesis) contains an explanatory note of 59 pages of the text, 4 tables, 13 figures, 39 references,

and 13 appendices;




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o Keywords: system MOODLE of remote education, object oriented environment, internet-pages, testing modules,

interactive elements, algorithmic languages and programming;

o Purpose of the Diploma work: a creation of Internet-pages by means of the remote education system MOODLE, which contain testing questions for the discipline “Algorithmic languages and programming” for conducting on-line testing of

students and listeners of the Siberian State Technological University (SibSTU);

o Investigation methods: in this work, the investigation methods are the built-in means of the Modular Object Oriented

Dynamic Learning Environment (MOODLE), i.e. application of the Internet technologies in the higher education for

remote education and testing of students;

o Investigation objective: the object of investigation is the testing module in the wide-spreaded Modular Object Oriented

Dynamic Learning Environment (MOODLE) which has an excellent recommendation.

04.2008 – 08.2008: short-time student (qualification improvement) in the Business School “Inoprof”,

Krasnoyarsk, Siberia, Russia. o studied the Microsoft Office program: Microsoft Word;

o studied the professional architectural program “AutoCAD”; drew some apartments for dwelling and café-restaurant;

o studied the three-dimensional graphics program “3ds max” and designed apartments with the program for dwelling and

café-restaurant of area by about 180 m2; prepared with the program presentational movie for the designed apartment.

09.2007 – 02.2008: Researcher (with Professor K.S. Kim), Pohang University of Science and Technology

(POSTECH), Pohang, South Korea. o worked as a researcher in the field of quantum chemistry/physics;

o designed different molecules, in general, acids;

o calculated binding energies for different super-molecules consisting of a sample acid molecule with a single

molecule(sometimes many water molecules) using the commonly-used quantum-chemistry ab initio computer program

“Gaussian-2003”. Used calculation methods are as follows: Becke-3-Lee-Yang-Parr (B3LYP) hybrid potential of density-

functional theory (DFT) methods and the Møller-Plesset second-order perturbation theory (MP2) with different

commonly-used basis sets like Aug-CC-pVXZ with X = D, T, or Q and improved 6-311++G** as well as the relativistic

effective core potential called CRENBL ECP for heavy atoms like iodine. One work was written and submitted to

www.arXive.org ;

o optimized sample structures and thermal characteristics for C18H20S2 using semi-empirical methods (for instance, PM3. ZINDO, etc.) that is useful for interactions with proteins;

o received some experience to calculate band structures for silicon (C, Ge, Pb, Sn, and Uuq) in diamond structure with the

ab initio computer program VASP (Viena Ab-initio Simulation Package);

o studied different coupled cluster theories, for instance, CCSD(T);

o donated some money in a church for new innovative solar-cell system with high efficiency of the light-to-electricity

conversion by about 50% up to 90% which will be soon used for heating, cooking, and light in the church;

o attended two workshops with banquets in January 2008 organized by the Asian Pacific Center for Theoretical Physics (the

12th APCTP Winter Workshop on Strongly Correlated Electron Systems in January 20-26, 2008 and APCTP Winter

School on Blake Hole Astrophysics in January 24-29, 2008) at the POSTECH, Pohang, South Korea.

04.2007 – 08.2007: Programmer, Siberian State Aerospace University, Krasnoyarsk, Siberia, Russia. o worked as a programmer.

2001 – present: Independent Researcher, 660037, Krasnoyarsk-37, 17701, Krasnoyarsk, Siberia, Russia.

It is thought that the non-dispersive Zakharenko type waves representing extreme points of the phase velocity Vph(kd), where

k is the wavenumber and d is the plate thickness, can be found in the lowest-order modes of Lamb type waves, when the

waves are studied in commonly used [100] and [110] propagation directions in crystals, for instance, non-piezoelectric cubic

crystals (metals). It is also thought that the non-dispersive Zakharenko type waves cannot exist in the modes of Lamb waves

propagating in isotropic plates that must be verified in experiments.

I have numerically discovered new dispersive shear-horizontal surface waves called ultrasonic surface Zakharenko waves (USZW), which can exist in some suitable propagation directions of piezoelectric coated crystals satisfying the condition of

perpendicularity between the wave propagation direction and an even-order symmetry axis, in which the dispersive surface

Bleustein-Gulyaev waves cannot exist, for example, in layered structures consisting of cubic crystals ([101] propagation

direction for both media). Also, unusual modes of Love type waves were found in the layered structures consisting of two

piezoelectric cubic crystals. Concerning piezoelectric cubic crystals, interesting solutions were analytically found studying

[101] propagation direction in the crystals. The solutions correspond to the phase velocity Vph0 = Vt4aK with aK = 2[K(1 +

K2)1/2 – K2]1/2 being lower than the speed Vt = Vt4(1 + K2)1/2 of the bulk shear-horizontal (SH) wave (Vt4 = (C66/ρ)1/2). A strong

dependence Vph0(K2) on the so-called static coefficient of electromechanical coupling (CEMC) K2 was found. It was also

found that for the phase velocity Vph < Vph0 there are all complex roots for any K2 including the special case of K2 = 1/3

where Vph0 = Vt. For Vph0 < Vph < Vt, the roots depend on K2: the roots are pure imaginary in monocrystals with K2 < 1/3, but

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real for strong piezoelectric cubic crystals with K2 > 1/3. The interesting feature is a very slow velocity Vph0 in weak

piezoelectrics with K2 < 1% (even K2 << 1%). The Vph0 calculation can be useful for finding new shear-horizontal (SH)

surface waves. The non-dispersive USZW-waves were discovered in my work: A.A. Zakharenko, JZUSA, 2007a.

I have analytically shown the possibility to find in crystals the other type of surface waves, representing a new supersonic

surface wave, polarized in the sagittal plane, like the surface Rayleigh waves are polarized, with the phase velocity, which is

higher than the speed Vl of the bulk longitudinal wave. Also, the anisotropy coefficient C2 = [(C11 – C55)(C33 – C55) – (C13 +

C55)2]/(C33C55) (see A.A. Zakharenko, NonDTE, 2006, and A.A. Zakharenko, ActaAA, 2005) was introduced representing

an universal characteristics for Rayleigh-polarized waves propagating in monocrystals and layered systems of all anisotropy

classes. I have found that the surface Rayleigh type waves can exist, if there is the following condition for negative C2 > – 1

– C11/C33 – 2(C11/C33)1/2.

I have numerically discovered the existence possibility of a new type of dispersive leaky waves in layered systems with

polarization, like the Love-wave (shear-horizontal) polarization. These new leaky type waves are called the dispersive leaky

Zakharenko type waves (see A.A. Zakharenko, JSV, 2005). It is noted that dispersive leaky Sezawa type waves possessing

the Rayleigh-wave polarization, as well as dispersive surface Rayleigh type waves, are readily observed with the same

experimental technique.

I have found that supersonic surface Love type waves can exist in layered systems owing to the anisotropy factor f = (C44C66 – C46

2)1/2/C44, in which such substrates as Muscovite, Phlogopite and Biotite (common micas) are used. Such shear-

horizontal supersonic surface LTW-waves can propagate with phase velocity which is higher than the speed Vl of the bulk

longitudinal wave for Diamond, Vl ~ 17500 [m/s] representing the fastest known velocity in Acoustoelectronics. (See A.A.

Zakharenko, NonDTE, 2005). Also, the paper (A.A. Zakharenko, NonDTE, 2005) offers a method for all-round automation

of filter and sensor characterization, as well as production.

I have also discovered two new types of surface waves (slow surface Zakharenko modes possessing slow speeds, single

modes and the LTW-polarization with the phase velocity lower than the LTW phase velocity). One new type of surface

waves can also exist when the LTW-waves can not propagate. (See A.A. Zakharenko, NonDTE, 2005). The slow surface

Zakharenko waves can be used for sensor and filter applications, like asymmetric Lamb waves (flexural plate waves) with

the Rayleigh-polarization are used generally operating in the 1-10 MHz frequency range. In general, technical devices are

based on waves with a velocity lower than that of sound in liquids. Currently, there is a great interest to Capacitive Micromachined Ultrasonic Transducers (CMUTs) of microelectromechanical system (MEMS) structures on the Lamb waves

in integrated circuit (IC) technology. The CMUTs can be also done using the slow surface Zakharenko waves that could be

even technologically preferable resulting in device prize reduction.

I have also studied the non-dispersive Zakharenko waves (see A.A. Zakharenko, ActaAA, 2005) in quantum systems,

studying both the bulk and surface elementary excitations (BEEs and SEEs) in the liquid helium-II at low temperatures (see

also A.A. Zakharenko, Forum Acusticum, Budapest, Hungary, 2005). Also, it was found that the Cooper pairing

phenomenon can exist in the BEEs’ positive roton branch at low temperatures, see A.A. Zakharenko, WRCM, 2007 as well

as A.A. Zakharenko, JZUSA, 2007b.

I have written my PhD-Theses in 2002 with the theme “Phonons, rotons and quantized capillary waves or ripplons in the

isotopically pure liquid 4He at low temperatures and properties of the liquid 4He surface”, Krasnoyarsk, Siberia, Russia,

2002. However, I still have not a PhD-degree, because the promotion was shifted to a far future due to obtained new results

written in my PhD-manuscript.

2000–2001: PhD-student training, School of Physics, Exeter University, Exeter, England, UK (with Dr.

C.D.H. Williams and Prof. A.F.G. Wyatt). Research topic: Quantum Fluids;

Measurements of experimental data with a dilution refrigerator in low temperature experiments;

I have worked on setups of vacuum evaporation (Zn, Silver), as well as discussions about obtained experimental data and

new experiments;

studied theoretically a probability of 4He-atom evaporation by the way doing numeric investigations;

There is one published paper in the JLTP in 2002 in collaboration with Prof. A.F.G. Wyatt and Dr. C.D.H. Williams.

2000: “Mitarbeiter”, 1st Physical Institute, Justus-Liebig-University, Giessen, Hessen, Germany (with

Prof. Dietrich Schwabe and Prof. Bruno K. Meyer). Worked on analysis of experimental data of space experiment “MAGIA” from the Russian satellite “FOTON-12”;

measured experimental data on a Czochralsky crystal growth simulation setup; Marangoni convection, Silicon oil with Pr

= 6.7.

1999: Engineer, Siberian State Aerospace University, Krasnoyarsk, Siberia, Russia (with Prof. E.V.

Babkin). o worked as an engineer;

o worked on a Russian vacuum evaporation setup.




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1998–1999: PhD-student training, Siberian State Technological University, Krasnoyarsk, Siberia, Russia

(with Prof. Yu.V. Zakharov).

There is one published paper (1999) in the Russian Journal of Computational Technologies (Novosibirsk).

I was studying complicated non-linear Physics; numeric investigations.

Results were presented in national and international science conferences.

1992–1998: Undergraduate student training, Krasnoyarsk State University, Krasnoyarsk, Siberia, Russia

(since 1997 with Prof. Yu.V. Zakharov). Diploma Physicist –Engineer-Physicist.

The Diploma work with the theme "Dynamical thresholds of stability and oscillations of elastic systems";

Results were presented in national student conferences.

1996–1997: Laboratory assistant in the computer laboratory “Exciton”, Krasnoyarsk State University,

Krasnoyarsk, Siberia, Russia. Computer modeling of elastic waves in layered systems;

Results were presented in national student conferences.

Teaching Experience:

1998 – 1999: Teaching assistant (Siberian State Technological University, Krasnoyarsk, Siberia, Russia).

Awards:

09.2007 – 02.2008: Pohang university of science and technology (POSTECH), Pohang, South Korea; the

head of the research group: Professor K.S. Kim (quantum chemistry).

10.2000 – 09.2001: British EPSRC, School of Physics, Exeter University, Exeter, England, UK; The head

of the research group: Professor A.F.G. Wyatt (quantum fluids); Supervisor: Dr. C.D.H. Williams;

Mentor: Dr. Alan Usher.

02.2000 – 09.2000: 1st Institute of Physics, Justus-Liebig University, Giessen, Germany; Director of the

Institute: Professor Bruno K. Meyer; Project Leader: Professor Dietrich Schwabe.

01.1998 – 09.1998 and 02.1999 – 05.1999: “Complex usage of Siberian Forests”, Siberian State

Technological University, Krasnoyarsk, Russia; Project Leader: Professor Yu.V. Zakharov.

Other conferences and attended courses:

22.07.2001 – 27.07.2001: International Symposium on Quantum Fluids and Solids, section “Excitations

in quantum systems” (Chairperson: M. Leduc), Dr. C.D.H. Williams has presented the following work:

C.D.H. Williams, A.A. Zakharenko, A.F.G. Wyatt, T25.7 - Rapid thermalisation in beams of strongly

interacting phonons; Universität Konstanz, Konstanz, Germany.

08.11.2000: Aston Business School, Birmingham, England, UK, Organized by the Low Temperature

Group of the Institute of Physics (in English).

09.2000 – 05.2001: Postgraduate courses in the School of Physics, Exeter University, Exeter, England,

UK (in English).

16.03.2000 – 17.03.2000: “FluidPac: post flight review” (MAGIA) organized by ESA, Nordwijk,

Netherlands (in English). I was there together with Professor Dietrich Schwabe with invitation from

Professor Antonio Verga.

03.1998 – 05.1999: Postgraduate courses at the Siberian State Technological University, Krasnoyarsk,

Siberia, Russia (in Russian).

21.09.97 – 25.09.97: Yu.V. Zakharov, A.A. Zakharenko. Dynamic loss of stability in non-linear problem

on cantilever and evaluation of catastrophe risk, Mathematical modeling of catastrophe and international

discussion: “Modern methods of modeling natural and technogene catastrophe”, Computational Center

SO RAS, Krasnoyarsk, Siberia, Russia.

26.04.1996: A.A. Zakharenko, Conditions of wave propagation in three-layered systems, Science

Conference of Student-Physicists (SCSP), Krasnoyarsk, Siberia, Russia (1996).




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Professional services:

2015-2017: An academic editor for the Physical Science International Journal (SCIENCEDOMAIN

international, Gurgaon, India).

2016-2017: A member of the board of editorial advisers for the Canadian Journal of Pure & Applied

Sciences (SENRA Academic Publishers, Burnaby, British Columbia, Canada).

2017: Invited Reviewer for a paper submitted to the Mechanics Research Communications (Elsevier).

2017: Invited Reviewer for a paper submitted to the Acta Acustica united with Acustica (S. Hirzel Verlag

– EAA, European Acoustics Association).

2016, 2015, 2010-2012: Invited Reviewer for several papers submitted to the IEEE Transactions on

Ultrasonics, Ferroelectrics, and Frequency Control.

2017-2012: Invited Reviewer for several papers submitted to the Open Journal of Acoustics (OJA,

Scientific Research Publishing, California, USA).

2015: Invited Reviewer for a paper submitted to the Zeitschrift fuer Angewandte Mathematik und

Mechanik (Wiley).

2015, 2014: Invited Reviewer for a paper submitted to the Meccanica (Italy, Springer Verlag).

2014, 2013: Invited Reviewer for papers submitted to the Journal of Vibration and Control (SAGE

Publishing).

2014: Invited Reviewer for a paper submitted to the British Journal of Applied Science & Technology

(BJAST, SCIENCEDOMAIN international, www.sciencedomain.org, see the last pages).

2014: Invited Reviewer for several papers submitted to the British Journal of Mathematics & Computor

Science (BJMCS, SCIENCEDOMAIN international, www.sciencedomain.org).

2015, 2014, 2013: Invited Reviewer for several papers submitted to the Physical Science International

Journal and the Physical Review & Research International (SCIENCEDOMAIN international).

2013: Invited Reviewer for several papers submitted to the Journal of Basic and Applied Physics (JBAP, the

World Academic Publishing Co., Limited, Hong Kong).

2017, 2014, 2012, 2006-2009: Invited Reviewer for several papers submitted to the Journal of Sound and

Vibration (Elsevier).

2014, 2013, 2011: Invited Reviewer for papers submitted to the IEEE/ASME Journal of

Microelectromechanical Systems (Taylor & Francis).

2011: Invited Reviewer for a paper submitted to the Canadian Journal of Pure & Applied Sciences

(SENRA Academic Publishers, Burnaby, British Columbia, Canada).

2017, 2016, 2015: Invited Reviewer for papers submitted to the Journal of Electromagnetic Analysis and

Applications (JEMAA, Scientific Research Publishing, California, USA).

2017, 2010: Invited Reviewer for several papers submitted to the Journal of Modern Physics (JMP,

Scientific Research Publishing, California, USA).

2013, 2008: Invited Reviewer for papers submitted to the International Journal of Solids and Structures

(Elsevier).

2007-2008: Invited Reviewer for a paper submitted to the Acta Mechanica (ACME).

2006-2009: Invited Reviewer for several papers submitted to the Waves in Random and Complex Media

(Taylor & Francis).

References:

1) RAS Academician V.F. Shabanov, Presidium of RAS Siberian Branch in Krasnoyarsk,

Akademgorodok, Krasnoyarsk, Siberia, Russia (see the last pages below).

2) RAS Academician K.S. Aleksandrov, L.V. Kirensky Institute of Physics, RAS Siberian Branch,

Akademgorodok, Krasnoyarsk, Siberia, Russia (see below).

3) Professor Dr. V.K. Andreev, Computational Center, RAS Siberian Branch, Akademgorodok,

Krasnoyarsk, Siberia, Russia (see below).

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4) Professor Dr. I.S. Edelman, L.V. Kirensky Institute of Physics, RAS Siberian Branch,

Akademgorodok, Krasnoyarsk, Siberia, Russia (see below).

Books and book chapters:

1) A.A. Zakharenko. Thirty Two New SH-Waves Propagating in PEM Plates of Class 6 mm.

Saarbruecken – Krasnoyarsk, LAP LAMBERT Academic Publishing GmbH & Co. KG, 162 pages,

2012, ISBN: 978-3-659-30943-4. This book is available on-line at

https://www.morebooks.de/store/gb/book/thirty-two-new-sh-waves-propagating-in-pem-plates-of-

class-6-mm/isbn/978-3-659-30943-4.

2) A.A. Zakharenko. Twenty Two New Interfacial SH-Waves in Dissimilar PEMs. Saarbruecken –

Krasnoyarsk, LAP LAMBERT Academic Publishing GmbH & Co. KG, 148 pages, 2012, ISBN: 978-

3-659-13905-5. This book is available on-line at https://www.morebooks.de/store/ru/book/twenty-

two-new-interfacial-sh-waves-in-dissimilar-pems/isbn/978-3-659-13905-5.

3) A.A. Zakharenko. Seven New SH-SAWs in Cubic Piezoelectromagnetics. Saarbruecken –

Krasnoyarsk, LAP LAMBERT Academic Publishing GmbH & Co. KG, 172 pages, 2011, ISBN: 978-

3-8473-3485-9. This book is available on-line at https://www.morebooks.de/store/gb/book/seven-

new-sh-saws-in-cubic-piezoelectromagnetics/isbn/978-3-8473-3485-9.

4) A.A. Zakharenko. Propagation of Seven New SH-SAWs in Piezoelectromagnetics of Class 6 mm.



https://www.morebooks.de/store/gb/book/propagation-of-seven-new-sh-saws-in-

piezoelectromagnetics-of-class-6mm/isbn/978-3-8433-6403-4.

5) A.A. Zakharenko. Dispersive SAWs in Layered Systems Consisting of Cubic Piezoelectrics.



https://www.morebooks.de/store/gb/book/dispersive-saws-in-layered-systems-consisting-of-cubic-

piezoelectrics/isbn/978-3-8433-7523-8.

6) A.A. Zakharenko. Ab Initio Study of Acid Molecules Interacting with H2O. Chapter 7 in: Advances in

Chemistry Research, Editor: James C. Taylor, Volume 5, pages 213 – 228, 2010, Nova Science

Publishers, Inc.; ISBN: 978-1-61728-773-2. This book is available on-line at

https://www.novapublishers.com/catalog/product_info.php?products_id=15791.

Publications:

1) A.A. Zakharenko. Complete list of all possible nondispersive SH-SAWs in 6 mm

magnetoelectroelastics: A comparative review. Sent for review () x (x) xxx – xxx (2019).

2) A.A. Zakharenko. On existence of new dispersive four-potential SH-waves in 6 mm plates for new

communication era based on gravitational phenomena. Sent for review () x (x) xxx – xxx (2018).

3) A.A. Zakharenko. On discovery of the twelfth and thirteenth new nondispersive SH-SAWs in 6 mm

magnetoelectroelastics. Sent for review () x (x) xxx – xxx (2018).

4) A.A. Zakharenko. Extra two new piezoelectromagnetic SH-SAWs with dramatic dependence on

small electromagnetic constant. Journal of King Saud University - Science (Production and hosting

by Elsevier B.V.) 30 (4) xxx – xxx (2018), ISSN: 1018-3647, DOI:

https://doi.org/10.1016/j.jksus.2017.05.005 .

5) A.A. Zakharenko. On new interfacial four-potential acoustic SH-wave in dissimilar media pertaining

to transversely isotropic class 6 mm. Canadian Journal of Pure and Applied Sciences (SENRA

Academic Publishers, Burnaby, British Columbia, Canada) 11 (3) 4321 – 4328 (2017); ISSN: 1715-

9997 (free on-line access at http://www.cjpas.org).

6) A.A. Zakharenko. The problem of finding of eigenvectors for 4P-SH-SAW propagation in 6 mm

media. Canadian Journal of Pure and Applied Sciences (SENRA Academic Publishers, Burnaby,

https://www.morebooks.de/store/gb/book/thirty-two-new-sh-waves-propagating-in-pem-plates-of-class-6-mm/isbn/978-3-659-30943-4

https://www.morebooks.de/store/gb/book/thirty-two-new-sh-waves-propagating-in-pem-plates-of-class-6-mm/isbn/978-3-659-30943-4

https://www.morebooks.de/store/ru/book/twenty-two-new-interfacial-sh-waves-in-dissimilar-pems/isbn/978-3-659-13905-5

https://www.morebooks.de/store/ru/book/twenty-two-new-interfacial-sh-waves-in-dissimilar-pems/isbn/978-3-659-13905-5

https://www.morebooks.de/store/gb/book/seven-new-sh-saws-in-cubic-piezoelectromagnetics/isbn/978-3-8473-3485-9

https://www.morebooks.de/store/gb/book/seven-new-sh-saws-in-cubic-piezoelectromagnetics/isbn/978-3-8473-3485-9

https://www.morebooks.de/store/gb/book/propagation-of-seven-new-sh-saws-in-piezoelectromagnetics-of-class-6mm/isbn/978-3-8433-6403-4

https://www.morebooks.de/store/gb/book/propagation-of-seven-new-sh-saws-in-piezoelectromagnetics-of-class-6mm/isbn/978-3-8433-6403-4

https://www.morebooks.de/store/gb/book/dispersive-saws-in-layered-systems-consisting-of-cubic-piezoelectrics/isbn/978-3-8433-7523-8

https://www.morebooks.de/store/gb/book/dispersive-saws-in-layered-systems-consisting-of-cubic-piezoelectrics/isbn/978-3-8433-7523-8

https://www.novapublishers.com/catalog/product_info.php?products_id=15791

http://www.cjpas.org/




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British Columbia, Canada) 11 (1) 4103 – 4119 (2017); ISSN: 1715-9997 (free on-line access at

http://www.cjpas.org).

7) A.A. Zakharenko. On piezogravitocogravitoelectromagnetic shear-horizontal acoustic waves.

Canadian Journal of Pure and Applied Sciences (SENRA Academic Publishers, Burnaby, British

Columbia, Canada) 10 (3) 4011 – 4028 (2016); ISSN: 1715-9997 (free on-line access at


8) A.A. Zakharenko. On discovery of extra four new dispersive SH-waves in magnetoelectroelastic

plates. Canadian Journal of Pure and Applied Sciences (SENRA Academic Publishers, Burnaby,

British Columbia, Canada) 10 (2) 3891 – 3903 (2016); ISSN: 1715-9997 (free on-line access at


9) A.A. Zakharenko. On separation of exchange term from the coefficient of the

magnetoelectromechanical coupling. Pramana – Journal of Physics (Indian Academy of Science) 86

(6) 1409 – 1412 (2016); DOI: https://doi.org/10.1007/s12043-015-1171-9, free on-line access at

http://www.ias.ac.in/pramana.

10) A.A. Zakharenko. On new dispersive SH-waves propagating in piezoelectromagnetic plate. Open

Journal of Acoustics (Scientific Research Publishing, Los Angeles, California, USA) 5 (3) 122 – 137

(2015); http://dx.doi.org/10.4236/oja.2015.53011 (free on-line access at

http://www.scirp.org/journal/oja).

11) A.A. Zakharenko. Dramatic influence of the magnetoelectric effect on the existence of the new SH-

SAWs propagating in magnetoelectroelastic composites. Open Journal of Acoustics (Scientific

Research Publishing, Los Angeles, California, USA) 5 (3) 73 – 87 (2015);

http://dx.doi.org/10.4236/oja.2015.53007 (free on-line access at http://www.scirp.org/journal/oja).

12) A.A. Zakharenko. A study of new nondispersive SH-SAWs in magnetoelectroelastic medium of

symmetry class 6 mm. Open Journal of Acoustics (Scientific Research Publishing, Los Angeles,

California, USA) 5 (3) 95 – 111 (2015); http://dx.doi.org/10.4236/oja.2015.53009 (free on-line access

at http://www.scirp.org/journal/oja).

13) A.A. Zakharenko. On existence of eight new interfacial SH-waves in dissimilar

piezoelectromagnetics of class 6 mm. MECCANICA (Publisher: Associazione italiana di meccanica

teorica e applicata, AIMETA, Italy, Springer Verlag) 50 (7) 1923 – 1933 (2015); DOI:

https://doi.org/10.1007/s11012-015-0210-4.

14) A.A. Zakharenko. An examination of zero-order modes of plate PEM-SH dispersive acoustic waves:

Magnetically open and electrically closed plate sides. Canadian Journal of Pure and Applied

Sciences (SENRA Academic Publishers, Burnaby, British Columbia, Canada) 8 (3) 3139 – 3145

(2014); ISSN: 1715-9997 (free on-line access at http://www.cjpas.org).

15) A.A. Zakharenko. Investigation of SH-wave fundamental modes in piezoelectromagnetic plate:

Electrically closed and magnetically closed boundary conditions. Open Journal of Acoustics

(Scientific Research Publishing, Los Angeles, California, USA) 4 (2) 90 – 97 (2014); DOI:

https://doi.org/10.4236/oja.2014.42009 (free on-line access at http://www.scirp.org/journal/oja ).

16) A.A. Zakharenko. Some problems of finding of eigenvalues and eigenvectors for SH-wave

propagation in transversely isotropic piezoelectromagnetics. Canadian Journal of Pure & Applied

Sciences (SENRA Academic Publishers, Burnaby, British Columbia, Canada) 8 (1) 2783 – 2787

(2014); ISSN: 1715-9997 (free on-line access at http://www.cjpas.org).

17) A.A. Zakharenko. New nondispersive SH-SAWs guided by the surface of piezoelectromagnetics.




18) A.A. Zakharenko. Fundamental modes of new dispersive SH-waves in piezoelectromagnetic plate.

Pramana – Journal of Physics (Indian Academy of Science) 81 (5) 819 – 827 (2013); DOI:

https://doi.org/10.1007/s12043-013-0609-1, free on-line access at http://www.ias.ac.in/pramana.

19) A.A. Zakharenko. Peculiarities study of acoustic waves’ propagation in piezoelectromagnetic

(composite) materials. Canadian Journal of Pure and Applied Sciences (SENRA Academic




http://www.ias.ac.in/pramana

http://www.scirp.org/journal/oja











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Publishers, Burnaby, British Columbia, Canada) 7 (2) 2459 – 2461 (2013); ISSN: 1715-9997 (free

on-line access at http://www.cjpas.org).

20) A.A. Zakharenko. Consideration of SH-wave fundamental modes in piezoelectromagnetic plate:

Electrically open and magnetically open boundary conditions. Waves in Random and Complex Media

23 (4) 373 – 382 (2013); DOI: https://doi.org/10.1080/17455030.2013.834396.

21) A.A. Zakharenko. Piezoelectromagnetic SH-SAWs: A review. Canadian Journal of Pure and

Applied Sciences (SENRA Academic Publishers, Burnaby, British Columbia, Canada) 7 (1) 2227 –

2240 (2013); ISSN: 1715-9997 (free on-line access at http://www.cjpas.org).

22) A.A. Zakharenko. A study of SH-SAW propagation in cubic piezomagnetics for utilization in smart

materials. Waves in Random and Complex Media 22 (4) 488 – 504 (2012); DOI:

https://doi.org/10.1080/17455030.2012.727042.

23) A.A. Zakharenko. On propagation problems of new surface wave in cubic piezoelectromagnetics.

Open Journal of Acoustics (Scientific Research Publishing, Los Angeles, California, USA) 2 (3) 104

– 114 (2012); DOI: https://doi.org/10.4236/oja.2012.23012 (free on-line access at

http://www.scirp.org/journal/oja).

24) A.A. Zakharenko. On wave characteristics of piezoelectromagnetics. Pramana – Journal of Physics

(Indian Academy of Science) 79 (2) 275 – 285 (2012); DOI: https://doi.org/10.1007/s12043-012-

0308-3, free on-line access at http://www.ias.ac.in/pramana.

25) M. Kolaski, A.A. Zakharenko, S. Karthikeyan, K.S. Kim. Structures, energetics, and IR spectra of

monohydrated inorganic acids: ab initio and DFT study. Journal of Chemical Theory and

Computation (Publisher: American Chemical Society) 7 (10) 3447 – 3459 (2011).

26) A.A. Zakharenko. Phase and group velocities of the surface elementary excitations on the superfluid

helium–II surface at low temperatures. Canadian Journal of Pure and Applied Sciences (SENRA

Academic Publishers, Burnaby, British Columbia, Canada) 5 (3) 1649 – 1655 (2011); ISSN: 1715-

9997 (free on-line access at http://www.cjpas.org).

27) A.A. Zakharenko. Analytical investigation of surface wave characteristics of piezoelectromagnetics

of class 6 mm. International Scholarly Research Network (ISRN) Applied Mathematics (India),

Volume 2011, Article ID 408529, 8 pages (2011); DOI: https://doi.org/10.5402/2011/408529 (free

on-line access).

28) A.A. Zakharenko. New interfacial shear-horizontal waves in piezoelectric cubic crystals. Journal of

Electromagnetic Analysis and Applications (Scientific Research Publishing, Los Angeles, California,

USA) 2 (11) 633 – 639 (2010); DOI: https://doi.org/10.4236/jemaa.2010.211083 (free on-line access

at http://www.scirp.org/journal/jemaa).

29) A.A. Zakharenko. Evidence of scattering of bulk elementary excitations in isotopically pure liquid

helium-II at low temperatures. Waves in Random and Complex Media 20 (3) 385 – 395 (2010); DOI:

https://doi.org/10.1080/17455030903536572.

30) A.A. Zakharenko. First evidence of surface SH-wave propagation in cubic piezomagnetics. Journal

of Electromagnetic Analysis and Applications (Scientific Research Publishing, Los Angeles,

California, USA) 2 (5) 287 – 296 (2010); DOI: https://doi.org/10.4236/jemaa.2010.25037 (free on-

line access at http://www.scirp.org/journal/jemaa).

31) A.A. Zakharenko. Slow acoustic waves with the anti-plane polarization in layered systems.

International Journal of Modern Physics B (World Scientific, Singapore) 24 (4) 515 – 536 (2010);

DOI: https://doi.org/10.1142/S0217979210054774.

32) A.A. Zakharenko. Studying magnetization distribution in magnetic thin films under transversal

application of magnetic fields. Journal of Modern Physics (Scientific Research Publishing, Los

Angeles, California, USA) 1 (1) 33 – 43 (2010); DOI: https://doi.org/10.4236/jmp.2010.11004 (free

on-line access at http://www.scirp.org/journal/jmp).

33) A.A. Zakharenko. Acoustic waves with the in-plane polarization in piezoelectric cubic structures.









http://www.scirp.org/journal/jemaa

http://www.scirp.org/journal/jemaa

http://www.scirp.org/journal/jmp





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34) A.A. Zakharenko. Different Zakharenko waves in layered and quantum systems. Conference

Proceedings of the International Commission for Acoustics (ICA2007 Congress, Madrid, Spain)

http://www.sea-acustica.es/WEB_ICA_07/fchrs/papers/phy-08-018.pdf, 4 pages (2007) DOI:

https://doi.org/10.13140/2.1.3607.6483.

35) A.A. Zakharenko. Creation evidence of the second non-dispersive Zakharenko wave by helium

atomic beams in superfluid helium–II at low temperatures. Pramana – Journal of Physics (Indian

Academy of Science) 69 (4) 617 – 629 (2007).

36) A.A. Zakharenko. Studying creation of bulk elementary excitation by heaters in superfluid helium–II

at low temperatures. Journal of Zhejiang University SCIENCE A 8 (7) 1065 – 1076 (2007); DOI:

https://doi.org/10.1631/jzus.2007.A1065.

37) A.A. Zakharenko. Creation of bulk elementary excitations in superfluid helium–II by helium atomic

beams at low temperatures. Waves in Random and Complex Media 17 (3) 255 – 268 (2007); DOI:

https://doi.org/10.1080/17455030601178164.

38) A.A. Zakharenko. New solutions of shear waves in piezoelectric cubic crystals. Journal of Zhejiang

University SCIENCE A 8 (4) 669 – 674 (2007); DOI: https://doi.org/10.1631/jzus.2007.A0669.

39) A.A. Zakharenko. On cubic crystal anisotropy for waves with Rayleigh-wave polarization. Non-

destructive Testing and Evaluation 21 (2) 61 – 77 (2006); DOI:

https://doi.org/10.1080/10589750600779704.

40) A.A. Zakharenko. Different dispersive waves of bulk elementary excitations in bulk superfluid

helium–II at low temperatures. In the CD-ROM Proceedings of the Forum Acusticum, Budapest,

Hungary (2005) pages L79 – L89; DOI: https://doi.org/10.13140/2.1.3869.7923.

41) A.A. Zakharenko. Analytical studying the group velocity of three-partial Love (type) waves in both

isotropic and anisotropic media. Non-destructive Testing and Evaluation 20 (4) 237 – 254 (2005);

DOI: https://doi.org/10.1080/17417530500513665.

42) A.A. Zakharenko. Dispersive Rayleigh type waves in layered systems consisting of piezoelectric

crystals bismuth silicate and bismuth germanate. Acta Acustica united with Acustica 91 (4) 708 – 715

(2005).

43) A.A. Zakharenko. Love type waves in layered systems consisting of two piezoelectric cubic crystals.

Journal of Sound and Vibration (Elsevier) 285 (4-5) 877 – 886 (2005); DOI:

https://doi.org/10.1016/j.jsv.2004.08.044.

44) C.D.H. Williams, A.A. Zakharenko, A.F.G. Wyatt. Narrow-angle beams of strongly interacting

phonons. Journal of Low Temperature Physics 126 (1–2) 591 – 596 (2002); DOI:

https://doi.org/10.1023/A:1013727403790.

45) Yu.V. Zakharov, A.A. Zakharenko. Dynamic loss of stability in non-linear problem about cantilever.

Journal of Computational Technologies (Novosibirsk, Russia) 4 (1) 48 – 54 (1999) (in Russian, but

abstract is in English).

46) A.A. Zakharenko. Dynamic thresholds of stability loss in the non-linear problem about cantilever.

Vestnik KSTU: Collected science articles of postgraduate and undergraduate students, KSTU

Publishers, Krasnoyarsk, Russia, 9, 160 – 164 (1997) (in Russian, under supervision of Prof. Yu.V.

Zakharov).

Published preprints:

1) A.A. Zakharenko. About dispersive waves of Rayleigh type in layered systems consisting of cubic

piezoelectric crystals Bi12SiO20 - Bi12GeO20. Preprint 4aaz – Krasnoyarsk, Siberia, Russia (2002) 8 pages,

edition 50.

2) A.A. Zakharenko. About waves of Love type in layered systems of cubic piezoelectric crystals

Bi12SiO20 - Bi12GeO20. Preprint 5aaz – Krasnoyarsk, Siberia, Russia (2002) 8 pages, edition 50.

3) A.A. Zakharenko, C.D.H. Williams₤. Evidence of creation of high-energy phonons by helium atom

beams. Preprint-3aaz – Krasnoyarsk, Siberia, Russia (2001), Exeter, England, UK (2000/2001) 12 pages,

edition 50.

http://www.sea-acustica.es/WEB_ICA_07/fchrs/papers/phy-08-018.pdf




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4) A.A. Zakharenko, C.D.H. Williams₤. Are rotons created directly by heater or by phonons around

heater? Preprint-1aaz – Krasnoyarsk, Siberia, Russia (2001), Exeter, England, UK (2000/2001) 16 pages,

edition 50.

5) A.A. Zakharenko. Quantized capillary waves or ripplons on the pure liquid 4He surface and properties

of the surface at low temperatures. Preprint-2aaz – Krasnoyarsk, Siberia, Russia (2001), Exeter, England,

UK (2000/2001) 36 pages, edition 50.

6) Yu.V. Zakharov, A.A. Zakharenko. Dynamic loss of stability in non-linear problem about cantilever

and discussion about risks of catastrophes. Preprint №780Ф. Krasnoyarsk, Siberia, Russia: Institute of

Physics SB RAS (1997) 8 pages, edition 70 (in Russian).

Published conference theses:

1) A.A. Zakharenko. Surface waves of Love type and Rayleigh type in layered systems consisting of

cubic piezocrystals bismuth germanate – bismuth silicate. Presentation theses of the 12th

winter School-

Seminar for Mechanics of Continuous Media, Perm’ (1999) page 149 (in Russian).

2) Yu.V. Zakharov, A.A. Zakharenko, V.G. Sukhovol’sky. Dynamic loss of stability in magnetic and

elastic systems. Presentation theses of the 12th

winter School-Seminar for Mechanics of Continuous

Media, Perm’ (1999) page 150 (in Russian).

3) Yu.V. Zakharov, A.A. Zakharenko. Dynamic loss of stability in magnetic and elastic systems under

transversal magnetic reversal and transversal loading. Theses of presentations of the XVI international

School-Seminar NMMM, Moscow, Russia (1998) ВЦ-34, page 542 (in Russian).

4) A.A. Zakharenko. Surface dispersive waves of Rayleigh type in layered system consisting of cubic

piezocrystals Bi12SiO20 - Bi12GeO20. Theses of the VI Russian science student conference, Tomsk, Siberia,

Russia (1998) page 71 (in Russian).

5) A.A. Zakharenko. Surface waves of Love type in layered system consisting of cubic piezocrystals

Bi12SiO20 - Bi12GeO20. Theses of the VI Russian science student conference, Tomsk, Siberia, Russia

(1998) page 70 (in Russian).

6) A.A. Zakharenko, Yu.V. Zakharov. Dynamic loss of cantilever stability under action of a transversal

loading. Theses of the Siberian School-Seminar “Mathematical Problems of Mechanics of Continuous

Media”, Novosibirsk, Russia (1997) page 61 (in Russian).

7) A.A. Zakharenko. Non-linear problem about cantilever. Dynamic loss of stability. Theses of the

science conference of students-physicists “Physics and Modern World-97”, Krasnoyarsk, Siberia, Russia

(1997) page 14 (in Russian, under supervision of Prof. Yu.V. Zakharov).

8) A.A. Zakharenko. Surface waves of Love type in layered system consisting of two anisotropic layers

on anisotropic substrate. Theses of the V Russian science student conference, Tomsk, Siberia, Russia

(1996) page 109 (in Russian). ₤ – I have paid to publish these two preprints in Krasnoyarsk, Siberia, Russia and contacted to Dr. C.D.H. Williams right away

after it. However, Dr. C.D.H. Williams disagrees with what is written in the preprints explaining me about it in an E-mail. I am

sorry about it.

Educational – methodical works:

1) T.S. Rozanova, N.N. Dyomina, A.A. Zakharenko. Studying the Kirchhoff’s law. Quantum Physics.

Methodical instructions to labor works for students of engineer specialties of SibSTU. SibSTU

Publishing, Krasnoyarsk, Siberia, Russia, № 100, ed. 300 (2000) 12 pages (in Russian).

2) T.S. Rozanova, N.N. Dyomina, A.A. Zakharenko, I.I. Uvaev. Evaluation of the Stephan-Boltzmann

constant. Quantum Physics. Methodical instructions to labor works for students of engineer specialties of

SibSTU. SibSTU Publishing, Krasnoyarsk, Siberia, Russia, № 101, ed. 250 (2000) 12 pages (in Russian).




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