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Prof. Jaroslav G. Klyushin
klyushin7748848@rambler.ru
Tel: +7 (812) 774-88-48

Pilotov St. 38
St. Petersburg
Russia

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Klyushin, Prof. Jaroslav G.     (Easy Link: http://www.worldsci.org/people/Jaroslav_Klyushin)
Professor of Physics, Editor of Galilean Electrodynamics East, President of ISC

Interests: Electrodynamics
Nationality: Russian
Age: 77
Born: 1940

Related Websites:
Galilean Electrodynamics International Physical Cong...


Books:
2012?????????????, ??????????, ??????? ? ?????? ?????
2009Fundamental Problems of Electrodynamics and Gravidynamics

Abstracts Online:
2008The John Chappell Memorial Lecture and Discussion
2004Proton Structure: An Experimental Approach
2004Hydrogen Atom Construction: A ?Non-Bohr' Approach
2005On Electrodynamic Forces
2005On Gravidynamic Forces
2005?Non-Bohr? Model of Hydrogen Atom
2005On Electron Movement in Ether
2006On Gravitational Belts in Atoms
2006On a Toroidal Model of the Neutron
2006On the Connection Between Electricity and Gravity
2003Mechanical Dimensionality for Electrodynamic Quantities
2003Generalized Lorentz Force Formula
2003Electro- and Gravi-Dynamics
2006Neutron Construction
1996A Generalized Formula for the Lorentz Force Density and Maxwell Equations
2007Gravidynamic Force
2007Electrodynamics and Gravidynamics
2009On Thermodynamic Fields
1996Expansion of Bohr's Quantum Postulates
2004Wave Solution of Generalized Maxwell Equations and Quantum Mechanics ? Part I
2005Wave Solution of Generalized Maxwell Equations and Quantum Mechanics ? Part II
2002Electron Dynamics in Ether
2000A Field Generalization for the Lorentz Force Formula
2010Mechanical Dimensionalities of Electrodynamic and Gravidynamic Fields
2011The Field Approach to Thermodynamics
2012The Thermodynamic Field's Cycles

Media Online:
2010-10-09VideoOn Thermodynamic Fields

Event Attendence:
2012-12-08The Maxwell Approach to GravityVideo Conference
2012-07-2519th Natural Philosophy Alliance ConferenceConference (Absentia)
2012-07-23International Congress 2012: Fundamental Problems of Natural Sciences and EngineeringConference will attend
2012-01-21The Field Approach to Thermodynamics and the Carnot Cycle, Part 2Video Conference
2011-10-29The Field Approach to Thermodynamics and the Carnot Cycle, Part 1Video Conference
2011-10-29The Field Approach to Thermodynamics and the Carnot Cycle, Part 1Video Conference
2011-07-0618th Natural Philosophy Alliance ConferenceConference (Absentia)
2010-10-09On Thermodynamic FieldsVideo Conference
2010-07-26International Congress 2010: Fundamental Problems of Natural Sciences and EngineeringConference
2010-06-2317th Natural Philosophy Alliance ConferenceConference (Absentia)
2010-03-06The Conflict Between Action at a Distance and Field TheoriesVideo Conference
2010-02-13Strategic Approaches To Facilitate Scientific ChangeVideo Conference
2010-02-06The Origin of the Universe and Its Subsequent EvolutionVideo Conference
2010-01-30Nonlinear Continuum Mechanics of Space and the Unified Field Theory - Part 1Video Conference
2010-01-23A Reality-Based Replacement for Quantum MechanicsVideo Conference
2010-01-16The Ten Assumptions of Science, Part 2Video Conference
2009-12-12Reference Frame Independent Dynamics, Or How to Get Off Einsteins Train, Part 2Video Conference
2009-12-05Non-Equilibrium Systems and Irreversible ProcessesVideo Conference
2009-11-21Expansion Tectonics GroupVideo Conference
2009-11-14Walther Ritz, Emission Theory and the Real WorldVideo Conference
2009-11-07The Electrodynamic Origin of the Force of Inertia (F = ma)Video Conference
2009-07-18An Approach to Gravity Modification as a Propulsion TechnologyVideo Conference
2009-05-2516th Natural Philosophy Alliance ConferenceConference
2008-08-04International Congress 2008: Fundamental Problems of Natural Sciences and EngineeringConference
2008-04-0715th Natural Philosophy Alliance ConferenceConference
2007-05-2114th Natural Philosophy Alliance ConferenceConference
2006-04-0313th Natural Philosophy Alliance ConferenceConference
2005-05-2312th Natural Philosophy Alliance ConferenceConference
2004-04-0711th Natural Philosophy Alliance ConferenceConference
2003-06-0910th Natural Philosophy Alliance ConferenceConference
1996-06-171996 International Scientific Conference on New Ideas in Natural ScienceConference

Biography

I was born in Leningrad in April of the year 1940. My father Gr. V. Klyshin worked as an engineer at tank plant. My mother, in her girlhood A.Y. Paletskaya, was a singer in the Leningrad Opera Theater at that time. Her father (my grandfather) was the grand grandson of a Polish insurgent exiled to Siberia for participation in the Kostzushko revolt against Russia. Her mother (my grandmother) was Georgian. I know nothing about her. My father's father (my grandfather) V.A. Klyushin worked as head of Kronstadt electric-power station during the year 1917 of the revolution. Kronstadt is a military sea base just near St. Petersburg (later Leningrad, and again St. Petersburg since 1991). He was said to be a man of soft benevolent character. He always tried to help everybody. Therefore his subordinates liked him.

My father inherited these features, and I did as well, it seems, though sometimes I feel the rebellious character of my other grandfather, and the emotions of my Georgian grandmother. My father's mentality helped him twice or thrice in his life. Kronstadt seamen were shock troops of the Bolshevik revolution. During the insurrection in October 1917, all fleet higher officers were killed in Kronstadt. My grandfather preserved his life even though his duty corresponded to vice-admiral rank. The station workers defended him. This was repeated in March of 1920, when the Kronstadt seamen already rebelled against Bolsheviks. The insurrection was suppressed under Trotsky's command. Any denunciation of any person meant that the person was em-barked into a ship hold, the ship went into the open sea, and kingstones were opened. Any chief has somebody who is dissatisfied with him. Therefore practically all chiefs of any rank were killed. My grandfather again became an exception. There were no denunciations of him. The station workers also helped my father when he tried to enter university. Only children of workers were permitted to join the university. The station workers wrote a special letter to the Bolshevik authorities to help my father.

My father's mother (my grandmother), in her girlhood A.G. Bosenko, was the daughter of a Ukranian peasant who grew rich and manged to organize the entry of his daughter into the Smolny Institute of Noble Girls, to which only daughters of noble men were usually permitted to enter. She studied very successfully, and graduated from Smolny Institute with the Big Golden Medal, a very rare award for excellent academic performance. In 1930 her husband and my grandfather, V.A. Klyushin, died after an unsuccessful appendix operation. My grandmother didn't marry again, but had, using present-day language, a 'boy-friend', Latvian by nationality. I do not know his name, but in 1937 he was arrested for 'nationalism', and sentenced to "10 years imprisonment without right to write letters." Nowadays we know this meant condemnation to death. Because my grandmother was not his official wife, she was not arrested, but just sent from Leningrad to the village Totszkoy in the Ural region, where she was allowed to live and work as a physician in accord with her previous specialty.

In May 1941 my father took me from Leningrad to her to have a rest in the village. "I shall take him in August", he said.  But on 22 of June 1941 a war between Hitlerist Germany and Stalinist USSR began. My father, together with personnel of the tank plant where he worked, was evacuated to Chelyabinsk (Ural region). He could not take me because he worked 12 hours a day without days off and could be arrested for being 5 minutes late. My mother came to me, but soon went to Chelyabinsk to her husband. It was decided that starvation in the village was not so strong as in the cities, and I was left with my grandmother for my whole life. as it turned out.

In 1949 my father went to Taganrog (Asov Sea) to work as a professor at the Radiotechnical Institute, which was organized there. We went to him, and just in time, because soon an experimental atomic bomb was exploded on the Totsky military site. I was told that after effects of this explosion are felt up till now.

By this time my father had already divorced from my mother.  She lived in Leningrad, and I with my father and grandmother in Taganrog. In 1953 my father went to work in Melitopol Agricultural Institute (Ukraine). I stayed with grandmother in Taganrog up to 1957, when I joined the Institute of International Relations in Moscow, Oriental Faculty, Burmese Language Group. There I first witnessed levitation of my Burmese lanquage teacher, which greatly impressed me, and later attracted my attention to the problems of gravity.

I studied international relations until 1962, the year when the KGB arrested me for "creation of an anti-soviet organization". The real cause was discussions that I organized among students and which were devoted to problems of democratization of the Soviet regime. The main point of my accusation was that I saw definite analogies between Hitler and Stalin. My KGB investigator told me, "You are lucky to have found yourself here nowadays. Five years ago I would do a roast beef from you."


Books by Prof. Jaroslav G. Klyushin



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Fundamental Problems of Electrodynamics and Gravidynamics

by Prof. Jaroslav G. Klyushin

KeyWords: Electrodynamics, Gravidynamics

Pages: 111
Publisher: Galilean Electrodynamics
Year: 2009
ISBN: 5988830137
ISBN: 978-0692003145
ISBN: 978-5846507425


Download and read it now

Description

This book presents a new approach to the Relativity Theory (RT) and Quantum Mechanics (QM). Besides the main motivation for the new approach ? that RT and QM appear to be incompatible with one another ? we note that a number of physically important cases and well documented experiments cannot be explained in the framework of the two theories. This approach has been presented at several conferences and symposia organized by International Scientists Club (ISC) in Russia and Natural Philosophy Alliance (NPA) in USA since 1990's.


View count: 38862
?????????????, ??????????, ??????? ? ?????? ?????

by Prof. Jaroslav G. Klyushin

KeyWords: ?????????????, ??????????, ???????, ?????, ???? ???????, ????????, ???????????, ??????

Pages: 259
Year: 2012
ISBN: 978-5-600-00029-2


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Description

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Papers by Prof. Jaroslav G. Klyushin



The John Chappell Memorial Lecture and Discussion

(2008)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

2008, 15th Natural Philosophy Alliance Conference, Albuquerque, NM, United States

Abstract:

From my point of view, the pressing questions include:
  1. Do you agree with Maxwell equations? What do they describe? Perhaps the direct force formulas by Gauss, Weber, Spencer et al, Grassman, Ampere, Wittaker are better in this or that aspect.
  2. Do Maxwell equetions describe interaction? If not does the Lorentz force formula do it OK? May we use one instead of the other? Your propositions?
  3. Why is the relativistic approach sometimes successful? Can we reach the same effects in another way? Does this other way predict anything in addition?
  4. Your opinion on the connections between electricity and gravity.
  5. The Gravifield has dimension of acceleration. In order to compare two different things, we must describe them with the help of the same language. What is the mechanical dimension of electricity?



Proton Structure: An Experimental Approach

(2004)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Proceedings of the NPA, Volume 1, No. 1, pp. 43-44

2004, 11th Natural Philosophy Alliance Conference, Denver, CO, United States

Abstract:

An earlier paper proposed equations of gravidynamic field, and based on that, a vortex-shaped model of the electron.  By analogy with the electron vortical model, a model of proton is here constructed.  Like the eletron, the proton is also considered as a massive vortical torus, but its equatorial angular velocity is 1863 times less and its meridional angular velocity is 3672 times more.



Hydrogen Atom Construction: A ?Non-Bohr' Approach

(2004)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Proceedings of the NPA, Volume 1, No. 1, pp. 45-48

2004, 11th Natural Philosophy Alliance Conference, Denver, CO, United States

Abstract:

This article further develops vortical models of the electron and the proton and the proton, in which each particle is a massive torus with two degrees of rotation.  The article is devoted to investigating standing waves originated in the ether by a proton.  Just such waves define discrete spectra of optical electrons and bremsstrahlung.  Standing waves in the vicinity of the proton define nuclear forces.



On Electrodynamic Forces

(2005)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

2005, 12th Natural Philosophy Alliance Conference, Storrs, CT, United States
Keywords: electrodynamic forces, Gauss-Weber electrodynamics

Lookup: weber (4), electrodynamics (68), electrodynamic (10), forces (11)

Abstract:

Historically, electrodynamics began when Gauss and Weber generalized Coulomb law for the case of moving charges. In the framework of this approach interaction force between two charges depends on their velocities difference, i.e. on their relative movement. Some authors (for instance [1]) show that this approach has not been exhausted yet. Spencer and her colleagues [2] have generalized this approach and shown that some experiments that cannot be explained within the framework of present-day electrodynamics may be naturally explained in terms of relative movement. These and other papers began a rebirth period for Gauss-Weber ideas. In particular Bernstein [3] shows that Weber?s formula has already covered all ?relativistic? effects. Historically, the Gauss-Weber approach was eclipsed by the field Maxwell approach, and forgotten by the end of 19th century. For instance, Einstein apparently didn?t know Weber?s papers. At any rate, he never mentioned Gauss and Weber, although the resemblance between the consequences of the two theories is surprising. Maxwell theory investigates the problem, not of charges interaction, but of the ?field? created by a moving charge in the surrounding space. In order to come to interaction force, an additional postulate is introduced. It is usually called Lorentz force formula. This formula describes interaction of the fields created by a moving charge with another charge called ?test charge?. This test charge is supposed not to create fields of its own but external fields created by the first charge are supposed to directly act on this test charge. Although Lorentz force formula predicts results of many experiments its effect in today form looks completely unsatisfactory. Many authors (for instance [2]) shows that Lorentz force formula isn?t able to explain a lot of experimental facts. Lorentz force asymmetry also leads to many theoretical and aesthetic problems. If it is considered exhaustive we come to contradiction to the third Newtonian law: it allows situations when one charge acts on the other and this other doesn?t act on the first one. In addition if we don?t accept either concept, then the very idea of ?absolute velocity? which appears in Lorentz force formula turns to be suspended. Actually dissatisfaction with this side of the formula stimulated Einstein with his Relativity Theory. In other terms Lorentz force formula in its present-day form is asymmetric and not universal. Ampere [4] and Whittaker [5] proposed formulas of their own to describe charge interaction force. They did this in terms of ?differential currents?. When paraphrased in terms of moving charges these formulas could expand and symmetries Lorentz force formula. But their ?field sense?, i.e., their connection with Maxwell equations, was not clear until recently. This paper?s author proposed certain generalization as Maxwell equation as Lorentz force formula [6], [7]. The generalized formula implies Lorentz, Ampere, Whittaker, Weber and Spenser formulas. It also includes some additional items not known previously. For instance it predicts cluster effect, Bohm-Aharonov effect and electro-weak interaction. The Weber formula has the same invalidity as the Lorentz one: it is asymmetric and not universal. The generalized formula includes items which make Weber formula symmetric and coordinate it to the whole set of experiments. The generalized formula for charge interaction is naturally modernized to describe photons interaction [8]. And this explains some quantum paradoxes.

References

  1. Andre K.T. Assis, Relational Mechanics (Apeiron, Montreal, 1999).
  2. D.E. Spencer, G. Coutu, W.W. Bowley, U.Y. Shama, P.J. Mann, "The Experimental Verification of the New Gaussian Equation for the Force between Moving Charges: Overhead Welding", International Conference on Space, Time and Motion., September 23-29, 1996, St. Petersburg, Russia.
  3. V.M. Bernstein, " Electrodynamics and Gravitation Based on Trends Preceeding Maxwell and Einstein", Galilean Electrodynamics 11, (5) 91 (2000).
  4. A.M. Ampere, Theorie mathematique des phenomenes electrodynamiques uniquement deduite de l?experience (Blanchard, Paris, 1958).
  5. E.T. Whittaker, A History of the Theories of Aether & Electricity, p 91 (Longman, Green and Co, London, 1910).
  6. J.G. Klyushin, " A Field Generation for the Lorentz Force Formula", Galilean Electrodynamics 11, (5), 83 (200).
  7. J.G. Klyushin, " Generalised Electrodynamics and Lorentz Force Formula", NPA conference proceeding, Storrs, Connecticut, 2003.
  8. J.G. Klyushin, " Wave Solution and Quantum Mechanics - Part 1", Galilean -Electrodynamics 15, Special Issues 2, GED ? East, Fall (2004).



On Gravidynamic Forces

(2005)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

2005, 12th Natural Philosophy Alliance Conference, Storrs, CT, United States
Keywords: gravidynamic field, Maxwell equations

Lookup: maxwell equations (9), field (99), equations (52), maxwell (22)

Abstract:

Papers [1] and [2] proposed to describe a gravidynamic field with the help of Maxwell type equations in which first time derivative is changed with the second one. Such a field is characterized by a certain constant that has dimension of acceleration. This characterizes a gravidynamic field just in the same sense as light velocity characterizes an electrodynamic field. One can say that electricity is the field of velocities and gravity is the field of accelerations. In order to describe interaction of two gravidynamic fields, a formula can be proposed similar to generalized formula for electrodynamic fields proposed in [3]. This formula shows that two masses interaction depends, not only on distance, but on accelerations and third and forth time derivatives in general. This is also similar to electric charge interaction, which depends on velocities and accelerations. In a static case, this formula naturally comes to Newton?s gravity law. The dynamic version of gravitational interaction predicts planets perihelion displacement, gravitational ?red shift?, differential rotation of the Sun and gaso-liquid planets, an additional force in galaxies which today is interpreted as ?dark mass?. On the Earth, this formula predicts continental drift, explains the observed character of oceanic and atmospheric currents, changes in the velocity of Earth rotation and some other effects. In the framework of this approach, a model of the electron as a massive torus is proposed. The mass drawing this torus performs two curling movement: in equatorial and meridional planes of the torus. Equatorial rotation defines charge and meridional rotation defines electron spin. Experiment shows that the force of electric repulsion of two electrons is 4.17 x 1042 times bigger than the force of their gravitational attraction. This helps to find angular velocity of electron equatorial rotation. It is 8.145 x 1020 rad/s. It coincides with De-Broglie frequency of electron in rest and radius of the greater circumference defining torus coincides with its Compton Wave length. If (omega) is the angular velocity of the electron equatorial rotation, then (...equation...) (1); Electron charge (...equation...)kg/c (2) Here m is electron mass also gained from electrodynamic reasoning and coinciding with the experimental value. Charge sign is defined by the screw which angular velocity of equatorial rotation constitutes with angular velocity of meridional rotation: it is right or left. If correlation (2) is established one can express all electrodynamic quantities in mechanical terms [4]. In particular dielectric constant has dimension of mass density and magnetic constant has dimension of compressibility of a certain medium that fills the space. Physical text books usually call it "physical vacuum". The author does not use this term because of its logic and aesthetic ugliness and prefers term "ether". Any "a priori" qualities are not prescribed to this term except those that are consequences of the experiments and proposed theories. In particular this means that light velocity in free ether is just speed of the sound in it and (...equation...) (3).

References

  1. J.G. Klyushin, "On the Maxwell Approach to Gravity", Report in seminar of St. Petersburg Physical Society, St. Petersburg, Russia, 1995.
  2. J.G. Klyushin, "Electro - and Gravidynamics", 13th NPA Conference, Storrs, Connecticut, 2003.
  3. J.G. Klyushin, "A Field Generalization for the Lorentz Force Formula", Galilean Electrodynamics, 11, (5) 83 (2000).
  4. J.G. Klyushin, "Mechanical Dimensions for Electrodynamic Quantities", Galilean Electrodynamics, 11, (5), 90 (2000).
  5. Additional information: http://www.physical-congress.spb.ru/.



?Non-Bohr? Model of Hydrogen Atom

(2005)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

2005, 12th Natural Philosophy Alliance Conference, Storrs, CT, United States
Keywords: hydrogen atom, local light velocity

Lookup: hydrogen atom (5), light (157), hydrogen (30), velocity (55), atom (15), local (2)

Abstract:

Corollaries of papers [1] and [2] are not only an electron model, but a proton model as well [3-5]. The proton is also a torus. Angular velocity amplitude of its equatorial rotation is 1836 times less than of electron. But angular velocity of its meridian rotation is 3765 times bigger. This last fact makes the situation in ether in the vicinity of the proton essentially other than in the case of electron. Local light velocity in the vicinity of electron is equal to light velocity c in free ether. But it is equal to sqrt2 c in the vicinity of the proton. It is evident that it must come to at a certain distance from proton. But this convergence turns out to be discrete and non monotonic. In other terms, the proton gives rise to a system of standing waves or curls in the surrounding ether. A local light velocity in this curls decrease to c/137 and then increase up to c making 137 steps. These 137 curls or force lines in Faraday terms differ from all the other in that their radius is greater and angular velocity is less than of electron. This means that electron can be inside these and only these curls. In particular this means that electron in unstirred hydrogen atom is in rest inside the first atomic force line with local light velocity c/137 . In multi-electronic atoms, electrons with non-zero orbital momentum move inside their maternal force line. But in order electron could move infinitely long it must move under conditions of superconductivity. It was shown in [6] that such electron must move with double local light velocity. When it is knocked out of its maternal force line it comes to new force line with less velocity than it is necessary for superconductive movement on this new line. It moves on the new line with friction. The accumulated energy is radiated and the electron comes back perhaps not on the very material but lower force line (force line with lower local light velocity).

References

  1. J.G. Klyushin, "On the Maxwell Approach to Gravity", Report in seminar of St. Petersburg Physical Society, St. Petersburg, Russia, 1995.
  2. J.G. Klyushin, "Electro - and Gravidynamics", 11th NPA Conference, Storrs, Connecticut, 2003.
  3. J.G. Klyushin, "Proton Construction: Experimental Approach", 12th NPA Conference, Denver, Colorado, 2004.
  4. J.G. Klyushin, "Hydrogen Atom Structure: Experimental Approach", 12th NPA Conference, Denver, Colorado, 2004.
  5. J.G. Klyushin, "A Field Generalization for the Lorentz Force Formula", Galilean Electrodynamics, 11, (5) 83 (2000).
  6. J.G. Klyushin, "Electron Dynamics in Ether", Galilean Electrodynamics, 13, Special Issues Number 2, GED-East, 37, Fall (2002).
  7. Additional information: http://www.physical-congress.spb.ru/.



On Electron Movement in Ether

(2005)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

2005, 12th Natural Philosophy Alliance Conference, Storrs, CT, United States
Keywords: ether, electrodynamics, gravidynamics

Lookup: aether (102), electrodynamics (68)

Abstract:

Theories of electro- and gravi-dynamics were proposed in [1], [2], and [3] yield that electric charge q moving with speed V is acted by force of ether resistance qV . This is an essential difference between electrically charged and electrically neutral body movement. In accord with well known Newton ether law doesn?t resist steady movement of electrically neutral body. Such resistance appears only when the body is accelerated. It is also well known that an external energy is necessary in order to sustain steady electric current. It is believed nowadays that this is because electrons in their movement collide with conductor?s atoms. But this is also necessary for charge movement in free ether. In other terms electron movement in free ether resembles rather car movement on a road then puck movement on ice. Electron moving with constant speed V is actually a neutral mass m moving with acceleration (omega)V, where (omega) is equatorial rotation angular velocity of the torus defining electron [3]. This problem is thoroughly investigated in [4]. Formulas describing electron movement under different conditions with subluminal and superluminal speed are found in [4]. In particular it is shown that electron must move with double local light velocity to achieve superconductivity. When matter temperature is lessened local light velocity in it is also lessened. And this enables electron moving with ordinary velocity to overcome super-conductivity barrier. It is shown in [5] that hydrodynamic effect of "additional mass" actually takes place in well known Kaufmann?s experiment now interpreted as ?relativistic effect?. This result takes place in full accord with above mentioned peculiarity of electron movement and generalized formula far Lorentz force [2].

References

  1. J.G. Klyushin, "On the Maxwell Approach to Gravity", Report in seminar of St. Petersburg Physical Society, St. Petersburg, Russia, 1995.
  2. J.G. Klyushin, "A Field Generalization for the Lorentz Force Formula", Galilean Electrodynamics, V11, D5, p83.
  3. J.G. Klyushin, "Electro - and Gravidynamics", 11th NPA Conference, Storrs, Connecticut, 2003.
  4. J.G. Klyushin, "Electron Dynamics in Ether", Galilean Electrodynamics, Fall Special Issue, D2, p37, 2002.
  5. J.G. Klyushin, "Generalized Electrodynamics about Forces Acting on Charge Moving in Capacitor and Solenoid", Proceeding of the Congress 2000, "Fundamental Problems of Natural Science and Engineering", v1, St. Petersburg, Russia.
  6. Additional information: http://www.physical-congress.spb.ru/.



On Gravitational Belts in Atoms

(2006)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Proceedings of the NPA, Volume 3, No. 1, pp. 112-115

2006, 13th Natural Philosophy Alliance Conference, Tulsa, OK, United States
Keywords: toroidal models, vortices

Lookup: vortices (2), models (12), toroidal (3)

Abstract:

In previous papers, toroidal models of electron and proton were proposed. Tangential velocities of the particles drawing electron torus surface are equal to light velocity c in free ether. Therefore, electron does not induce additional vortices in ether at least as a first approximation. Meridional velocity of the particles drawing proton are 1.42c. This explains why proton induces series of vortices in the proton surrounding ether. The local light velocities in the first 194 vortices decrease up to (...) and then increase up to (...) making steps. Nuclear 194 vortices have mass of proton and atomic 137 vortices have mass of electron. There exists a transition belt of 1836 vortices between 194 nuclear and 137 atomic lines. Local light velocity in these 1836 vortices is stable and equal to (...)/137 and their mass decreases from the proton mass to the electron mass. Such gravitational belts with decreasing mass are essential in multi-electronic atoms. In particular, they define quantity of electrons in hulls(sp?) and character of X-ray radiation.



On a Toroidal Model of the Neutron

(2006)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

2006, 13th Natural Philosophy Alliance Conference, Tulsa, OK, United States
Keywords: vortical models, neutron

Lookup: neutron (14), models (12)

Abstract:

In the author's previous papers vortical models of electron and proton as a torus were proposed. Torus mass performs two rotational movements, in equatorial and meridional planes. Equatorial rotation defines electric charge and meridional rotation defines its spin. If the vectors of equatorial and meridional rotation constitute right triple, the particle posesses charge of one sign; if they constitute left triple, the opposite sign. The author's other papers tried to clarify the concept of magnetic moment for electron and proton and its connection with generalized Maxwell equations. This paper investigates the same problems for the neutron



On the Connection Between Electricity and Gravity

(2006)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Proceedings of the NPA, Volume 3, No. 1, pp. 109-111

2006, 13th Natural Philosophy Alliance Conference, Tulsa, OK, United States
Keywords: Coulomb law, Maxwell equations, Lorentz force

Lookup: lorentz force (10), maxwell equations (9), law (61), force (74), equations (52), lorentz (73), maxwell (22), coulomb (6)

Abstract:

Gauss and Weber proposed generalization of Coulomb?s law for the case of moving charges.Such interaction depends on relative velocities and accellerations of the charges. When Maxwell field approach was accepted by scientific community, Lorentz proposed his force formula which describes interaction between electric and magnetic fields induced in the space by a certain charge and another charge called test charge. Actually this formula describes interaction between these charges and depends on absolute velocities of the charges. It does not take into consideration charges? accelerations, and does not cover other force formulas proposed by Ampere, Whittaker and Gauss, although all of them were confirmed by experiment. A formula covering all mentioned ones and introducing some additional items was proposed by the author as a generalization of Maxwell?s equations and Lorenz force formula. The proposed report is devoted to analyses of gravidynamic force, which generalizes Newton?s gravitational law in the case of moving masses. It includes second, third, and fourth time derivatives.

This paper is aka "On Gravidynamic Force".






Generalized Lorentz Force Formula

(2003)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Journal of New Energy, Volume 7, No. 3, pp. 53-56

2003, 10th Natural Philosophy Alliance Conference, Storrs, CT, United States
Keywords: Lorentz Force

Lookup: lorentz force (10), force (74), lorentz (73)




Electro- and Gravi-Dynamics

(2003)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Journal of New Energy, Volume 7, No. 3, pp. 57-60

2003, 10th Natural Philosophy Alliance Conference, Storrs, CT, United States

2008, International Congress 2008: Fundamental Problems of Natural Sciences and Engineering, 190040 St. Petersburg, Russia
Keywords: Electrodynamics, Gravity

Lookup: gravity (124), electrodynamics (68)




Neutron Construction

(2006)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp



Proceedings of the NPA, Volume 3, No. 1, pp. 105-108

2006, 13th Natural Philosophy Alliance Conference, Tulsa, OK, United States
Keywords: electron, proton, torus, electric charge, spin

Lookup: electron (46), proton (10), spin (14), torus (4), electric charge (6), electric (45), charge (49)

Abstract:

In papers and vortical models of electron and proton as a torus were proposed. Torus mass performs two movements: in equatorial and meridional planes. Equatorial rotation defines electric charge and meridional rotation its spin. If vectors of angular velocities in equatorial and meridional planes constitute right triple the particle possesses charge of one sign if they constitute left triple- the opposite one.

In paper concept of magnetic moment of electron and proton and its connection with idea of magnetic charge in generalized Maxwell equations was investigated. This paper tries to clarify sense of all those concepts for neutron.



A Generalized Formula for the Lorentz Force Density and Maxwell Equations

(1996)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

Proceedings of the 1996 International Scientific Conference on New Ideas in Natural Science , pp. 251-260


1996, 1996 International Scientific Conference on New Ideas in Natural Science, St. Petersburg, Russia
Keywords: Lorentz Force Density, Maxwell's Equations

Lookup: maxwell equations (9), force (74), equations (52), lorentz (73), maxwell (22), density (7)




Gravidynamic Force

(2007)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Proceedings of the NPA, Volume 4, No. 1, pp. 111-115

2007, 14th Natural Philosophy Alliance Conference, Storrs, CT, United States

Abstract:

Certain generalization of Maxwell equations was proposed in paper [1]. It implies total time derivatives instead of the partial ones. Partial solution of this system was found for the case of the fields induced by electric charges. Scalar product of electric fields created by different charges determines their interaction energy and vector product of their magnetic fields determines their interaction impulse. Having calculated interaction energy gradient we obtain interaction force as Huygens understood it and having calculated impulse total time derivative we obtain Newton?s interaction force. It turns out that these forces physical sense and their mathematical description essentially differ. Gradiental part depends on charges velocities product and is equal to zero if at least one of the charges is in rest. This part incorporates force formulas earlier proposed by Ampere, Whittaker and Lorentz. The last one is usually defined by interaction of a certain charge called test charge and fields induced by other charge. Actually it coincides with force formula proposed by Grassman earlier. Proposed formula in contrast to Lorentz one satisfies the third Newtonial law. The second Newtonian part of the force formula depends on differences product of the charges velocities and accelerations. Therefore it predicts interaction in particular between moving and standing charges in addition to Coulomb one. It contains items earlier proposed for force description by Gauss and Weber. As in the case of Lorentz force formula it adds items which make Gauss and Weber force symmetric. Certain part of this force is light velocity c2 inverse and a part of it is c3 inverse. Apparently these items are essential for electroweak interaction. This paper is devoted to similar investigation of gravitational forces created by moving masses. Corresponding fields are described by Maxwell type equations in which first time derivatives are changed for the second ones. One can say that Electricity is a field of velocities and gravity is a field of accelerations. Solutions of such a system are used to construct interaction energy and interaction impulse. Gradient of scalar product of corresponding gravitational fields and second time derivative of vector product of gravimagnetic fields turn to be accurate analogues of electrodynamic interaction. But here forces depend not only on velocities and accelerations but on third and fourth derivatives as well.



Electrodynamics and Gravidynamics

(2007)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

2007, 14th Natural Philosophy Alliance Conference, Storrs, CT, United States

Abstract:

Connections between electricity and gravity are investigated.



On Thermodynamic Fields

(2009)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

2009, 16th Natural Philosophy Alliance Conference, Storrs, CT, United States

Abstract:

The concept of thermodynamic fields is introduced, and a mathematical apparatus for its description is proposed. Such an approach enables one to shine a new sight on a lot of problems; for instance, on the second principle thermodynamics, Planck?s formula, Heizenberg?s uncertainty principle.



Expansion of Bohr's Quantum Postulates

(1996)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp

Proceedings of the 1996 International Scientific Conference on New Ideas in Natural Science , pp. 117-122


1996, 1996 International Scientific Conference on New Ideas in Natural Science, St. Petersburg, Russia
Keywords: Bohr, Quantum Postulates

Lookup: bohr (4), quantum (151), postulates (10)




Wave Solution of Generalized Maxwell Equations and Quantum Mechanics ? Part I

(2004)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Galilean Electrodynamics, Volume 15, No. S2, pp. 30-34

Abstract:

A wave version for generalized Maxwell equations is proposed. The wave created by a moving electron is described on the basis of a torus model proposed earlier in a paper devoted to a Maxwell approach to gravity. This wave is described by torsion oscillations. A corresponding vortex carries mass. Therefore, moving electrons and photons possess qualities as both waves and particles. Conformity of the derived results with experiments underlying quantum mechanics is verified. A fact that staggered the author was found: the electron creates a time-independent standing wave that defines the Coulomb force. In particular, this means that the Coulomb force is a long-range one.




Wave Solution of Generalized Maxwell Equations and Quantum Mechanics ? Part II

(2005)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Galilean Electrodynamics, Volume 16, No. S1, pp. 3-7

Abstract:

The traditional Lorentz force formula involves a probe charge and an externally generated electromagnetic field that acts on that charge. Therefore, the Lorentz force formula is incapable of describing the interaction of photons, which possess electromagnetic field but do not possess charge. On the basis of a generalized force formula proposed in Part I, which describes the interaction of electromagnetic fields independent of whether they are originated by charges or not, formulas for momentum, energy, and force interaction between two photons, two charges, or one charge and a photon, are found here.




Electron Dynamics in Ether

(2002)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Galilean Electrodynamics, Volume 13, No. S2, pp. 37-40

Abstract:

A model is proposed in which an electron moves in a fluid medium, or ether, which is assumed to fill all space. This model explains many ?relativistic? effects, plus the results of many experiments that are now explained in only an ad hoc manner, or not explained at all.



A Field Generalization for the Lorentz Force Formula

(2000)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Galilean Electrodynamics, Volume 11, No. 5, pp. 83-89

Abstract:

 It is difficult to find critical work about Einstein's Theory of Relativity in most standard physics journals. Galilean Electrodynamics, founded by the late Dr. Petr Beckmann in 1989, is a notable exception. Since Einstein's 1905 paper, Relativity has had many critics and although it is widely accepted today, there is still a minority who question the central tenets of Relativity Theory. Galilean Electrodynamics is devoted to publishing high quality scientific papers, refereed by professional scientists, that are critical of Special Relativity, General Relativity, Quantum Mechanics, Big Bang theory and other establishment doctrines.



Mechanical Dimensionalities of Electrodynamic and Gravidynamic Fields

(2010)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
(Absentia)



Proceedings of the NPA, Volume 7, pp. 257-259

2010, 17th Natural Philosophy Alliance Conference, Long Beach, CA, United States

Abstract:

A system of mechanical dimensionalities is proposed for electrodynamics. It turns out that permittivity has the dimension of mass density. Therefore, the electric permittivity constant is interpreted as ether mass density. The vacuum magnetic permeability has dimension of compressibility, and it is therefore interpreted as free ether compressibility. The electric field has dimension of velocity. That enables us to compare its qualities with those of gravity, which has dimension of acceleration.



The Field Approach to Thermodynamics

(2011)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Yegor V. Pesterev
prospect Pjatiletok 14/2 118, St. Petersburg 193318, Russia; yogurt@live.ru, 7(911)7548128, www.scicommunity.ru
(Absentia)



Proceedings of the NPA, Volume 8, pp. 313-322

2010, On Thermodynamic Fields, United States

2011, 18th Natural Philosophy Alliance Conference, College Park, MD, United States

Abstract:

The concept of thermodynamic fields is introduced, and a mathematical apparatus for its description is proposed. Such an approach enables us to shed new light on a lot of problems; for instance, on the second principle of thermodynamics, Planck's formula, and Heisenberg's uncertainty principle. It is an old idea that Brownian motion is essential for description an solution of the Quantum Mechanics problems. Nonstohastic description Brownian motion is also proposed using tensor mathematics.



The Thermodynamic Field's Cycles

(2012)

Prof. Jaroslav G. Klyushin
Pilotov St. 38, St. Petersburg, Russia; klyushin7748848@rambler.ru, +7 (812) 774-88-48, www.physical-congress.spb.ru/2008en.asp
Yegor V. Pesterev
prospect Pjatiletok 14/2 118, St. Petersburg 193318, Russia; yogurt@live.ru, 7(911)7548128, www.scicommunity.ru



Proceedings of the NPA, Volume 9, pp. 266-270

2012, 19th Natural Philosophy Alliance Conference, Albuquerque, NM, United States

Abstract:

The field approach to thermodynamics, proposed by the authors in [1], is used to analyze field cycles similar to the Carnot cycle. The evaluation of energy losses in such cycles turns out to be qualitatively similar to Carnot but there are some essential differences between them. The field estimation includes dependence on a greater number of parameters and contains not only initial and final temperature. This additional dependence let us formulate recommendations to optimize the work of heat engines and the necessary conditions for the efficiency coefficient to exceed 1.

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