7. A UNIFICATION OF ELECTROSTATIC AND GRAVITATIONAL FORCES. Abstract



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7. A UNIFICATION OF ELECTROSTATIC AND RAVITATIONAL FORCES Abstract The gravitational force of attraction F between two bodies, distance apart, one of mass M 1 containing N 1 positive and negative electric charges (±Q i ) and the other of mass M containing N electric charges (±K i ), is derived as: N1 N F = M 1M o o QV i i o o Ki Pi û = µ ε µ ε û i= 1 i= 1 where is the gravitational constant, µ o the permeability and ε o the permittivity of a vacuum, V i and P i are the total potentials at the respective locations of the charges Q i and K i and û is a unit vector. This explains Newton s universal law of gravitation, as an electrical effect, outside Einstein s theory of general relativity. ravitation is attributed to deflection of electric fields by charges such that forces of repulsion are decreased and forces of attraction increased. Keywords: Electric charge, force, gravity, mass, relativity. 7.1 Introduction The force of attraction between two bodies is given by the universal law of gravitation discovered by Sir Isaac Newton around 1687 [1]. The force of attraction or repulsion between two stationary electric charges is expressed by the law of electrostatics enunciated by Charles Coulomb in 1784. It is natural that physicists would think that there should be a connection between gravitational and electrostatic forces. So, for several decades now, physicists have been searching for a theory that would combine gravitational forces between masses and electrostatic forces between charges. In 1915, Einstein [] came out with the general relativity theory. This, it was believed, explained gravitation in the context of curvature or warping of four-dimensional space-time. The idea of four-dimensional space-time continuum, where the three spatial coordinates and the one time dimension pinpoint an event in space, - 81 - A unification of electrostatic and gravitational forces

was first suggested by the erman physicist Herman Minkowski, in 1908. Minkowski s idea was subsequently adopted by Albert Einstein in formulating the theory of general relativity. According to the general relativity theory, gravity is not a force like other forces, but the result of curvature or warping of four-dimensional space-time due to the presence of matter; not some effect emanating from matter itself. Bodies, like the earth, follow the path of least resistance, a straight line in curved space-time, which, in reality, is an elliptic orbit in three-dimensional space. In other words, curved space pushes (accelerates) objects to follow a particular path in the universe. Where the space-time curvature is infinite, there is what is called singularity, resulting in a black hole - matter so dense and massive that not even light can escape from its vicinity, boundary or event horizon. The idea of warping of space-time, referred to as ripples of space (due to time effect), in the presence of matter, giving rise to gravitation, was a revolutionary, brilliant and most appealing theory. The general relativity theory or Einstein s theory of gravitation, describes the large-scale structure of the universe and the force of gravity or acceleration between bodies, like the sun, planets and moons. Quantum mechanics based on the works of Planck, Bohr, De Broglie and others [3, 4, 5], on the other hand, treats extremely small-scale phenomena down to the atomic particles. Unfortunately, the quantum and relativity theories, the dominant theories of modern physics, being incompatible with one another at high speeds, cannot both be correct, but do coexist peacefully. This inconsistency has informed the search for a unified theory to incorporate general relativity and quantum mechanics a quantum theory of gravity or quantum field theory. Einstein spent many years searching for a link between general relativity and quantum theory, up to the end of his life, without success. Many physicists are now engaged in the search for a unified field theory or rand Unified Theory (UT). Just as Einstein introduced time making a fourth (non spatial) dimension in general relativity, to explain gravitation, in 1919 the Polish mathematician, Kaluza, proposed that a fourth spatial dimension was needed to incorporate electrical forces. This proposal was subsequently refined in 196 by Swedish physicist, Klein. Kaluza and Klein suggested that electromagnetism was due to ripples in four spatial dimensions and one time dimension. The idea of space having more than three dimensions (the usual three extended dimensions and several curled up dimensions - 8 - A unification of electrostatic and gravitational forces

too small to be observed) was a brilliant and very attractive theory. Thistheory has stretched physicists dimensions of imagination too far, but so far, it has not been demonstrated by any experiment. In the early 1980s the search for a unified field theory assumed extra dimensions with the introduction of the superstring theories as described by Hawking [6], reene [7] and Barbour [8]. According to the union of five types of superstring theories, called the M-theory ( M for mysterious), the fundamental constituents of the physical world are not point particles but infinitesimal one-dimensional open strings (lines) or closed strings (loops). All the forces and energies in the universe arise from the strings vibrations at different frequencies in ten spatial dimensions and one time dimension; an elementary particle, like the electron, being a string vibrating at a resonant frequency. The advocates of the M-theory take it as the rand Unified Theory (UT) of everything. Some other physicists have been engaged in the pursuit for a unified field theory but not along the lines of reconciling general relativity and quantum mechanics. It may as well be that either the general relativity theory or quantum mechanics is incorrect or that both theories are wrong. It is not so much like looking for the proverbial needle in the haystack but searching for something that was not a needle or never in the haystack. What is needed is to go back to the first principles and conduct the search on the basis of the well-known Newton s universal law of gravitation and Coulomb s law of electrostatics. 7. Newton's universal law of gravitation The law of force of attraction between masses in space was discovered by the great English physicist and mathematician, Sir Isaac Newton around 1687 [1]. Newton s law of gravitation states: Every object in the universe attracts every other object with a force that is proportional to the product of their masses and inversely proportional to the square of the separation between the two objects. Mathematically, the gravitational force of attraction F between two objects of masses M 1 and M in space separated by a distance, between their centres of mass, is expressed as: - 83 - A unification of electrostatic and gravitational forces

M1M F = û (7.1) where û is a unit vector pointing in the direction of the force of repulsion, opposite to the force F and is the gravitational constant. 7.3 Coulomb s law of electrostatics The American politician, scientist and inventor, Benjamin Franklin (1706 1790) had established that there were two kinds of electricity, positive charges and negative charges. He demonstrated that electric charges always existed in equal and opposite amounts. Franklin s discovery was of great significance in physics. Thus, for neutral bodies the forces of repulsion and attraction, due to the equal number of positive and negative charges, cancel out exactly. There is no electrostatic force of repulsion or attraction between two neutral bodies, but the gravitational force of attraction remains and persists. Forces between stationary electric charges are expressed in the law enunciated by the French physicist, Charles Coulomb, in 1785. Coulomb s law of electrostatics, a significant law in physics, states: The force of repulsion or attraction between two electric charges is proportional to the product of the magnitude of the charges and inversely proportional to the square of the distance between them. An addition to Coulomb s law is to the effect that Like charges repel and unlike charges attract, This is in contrast to gravitation where the forces are always attractive. The electrostatic force f E, of repulsion or attraction, between two stationary electric charges of magnitudes Q and K distance apart, in space, is expressed as a vector: QK fe = ± û (7.) where the force between two electric charges is positive (repulsive) for like charges and negative (attractive) for unlike charges, ε o is the permittivity of a vacuum and the unit vector û points in the direction of the force of repulsion. - 84 - A unification of electrostatic and gravitational forces o

7.4 Electrostatic and gravitational forces between two isolated charges Figure 7.1 shows two isolated electric charges of magnitudes Q and K respectively in the form of spherical shells of radii a and b. The masses m 1 and m are separated by a distance in space. is very much larger than the radius a or b. The force f between the stationary charges, which is a combination of electrostatic force of repulsion or attraction and gravitational force of attraction, is expressed as: QK m1 m f = ± û û (7.3) o Q K m 1 a û b m Figure 7.1. Electrostatic and gravitational forces between two charges Q and K. where û is a unit vector in the direction of force of repulsion and is the gravitational constant. The first term on the right-hand side of equation (7.3) is the electrostatic force of repulsion or attraction between isolated electric charges of magnitudes Q and K and the second term is the gravitational force of attraction f, between masses m 1 and m, as given by Newton s universal law of gravitation. Equation (7.3) gives the gravitational force, equation (7.1), as: f = m 1 m û (7.4) The author [9] showed that the mass m of an isolated electric charge (positive or negative) of magnitude Q, in the form of a spherical shell of radius a in free space of permeability µ o, is given by the equation: µ Q o m = (7.5) 4π a Substituting for the mass m 1 (of electric charge Q) and mass m (of another electric charge K) from equation (7.5) into (7.4), gives the gravitational force of attraction. The gravitational force of attraction between two isolated electric charges, where the separation is much larger than the radius a or b, is given by the vector equation: - 85 - A unification of electrostatic and gravitational forces

µ oq µ o K f = m 1mû = û (7.6) 4π a 4π b µ o Q K ζ Q K f = ab = 4π û û (7.7) where ζ (zeta) is a constant. Thus f, the force of attraction due to gravity, is proportional to the product of square of the charges or proportional to the square of product of the charges. This force is always negative (attractive) because the square of an electric charge (positive or negative) is always positive. A unification of electrostatic and gravitational forces gives the force between two electric charges Q and K separated by distance in space (equation 7.3) as: QK ζ f = ± û Q K o û (7.8) For a neutral body containing equal numbers or equal amounts of positive and negative electric charges the forces of repulsion and attraction cancel out exactly but the gravitational forces of attraction add up. 7.5 Electrostatic force of repulsion and attraction between two neutral bodies Figure 7. shows a neutral body of mass M 1 containing N 1 / positive electric charges and N 1 / negative electric charges, N 1 being an even number and a very large number indeed. Each charge is of quantity ±Q i = ( 1) i Q i, in the form of a spherical shell of radius a i (i = 1,, 3, 4...N). The potential p i at a point R, due to a charge Q i distance i from R, is: ( 1) Qi pi = oi The electrostatic potential P, at a point R, due to all the N 1 / positive electric charges and N 1 / negative electric charges in a neutral body of mass M 1, is the sum: N1 N1 1 i Qi 1 i P = ( 1) = ( 1) Qi (7.9) o i= 1 i o i= 1-86 - A unification of electrostatic and gravitational forces i

- + - + X i + - + - Q i - 87 - A unification of electrostatic and gravitational forces i - + - + K i + -O + - R - + - + M + - + a i M 1 Figure 7.. A body of mass M 1 containing N 1 positive and negative charges each of magnitude Q i at a distance i from a point R with mass M in space. Two constituent charges, each of radius a i, making a pair of particles, are separated by a distance X i, much lager than a i. The distance i is much larger than X i. where is the distance of the centre of charge O from the point R in space. Since a neutral body is composed of equal numbers or equal amounts of positive and negative electric charges, the potential at R, is: N1 N1 N1 1 i 1 P = ( 1) Q i Qi Q = ( 1) 0 i o i= 1 o = (7.10) i= 1 i= 1 N 1/ N 1/ where ΣQ i is the total amount of positive charges, equal to ΣQ (i -1) i = 1 i = 1 the total negative charges in a neutral body. Equation (7.10), making the potential at any point, due to a neutral body, zero, is stating the obvious. This is quite obvious for electric charges equal in magnitude. A second neutral body of mass M placed at R (Fig. 7.) experiences a constant (0) potential and no electrostatic force, as the forces of repulsion and attraction cancel out exactly, leaving the gravitational forces. 7.6 ravitational force between two bodies The author [9] showed that the mass M of a distribution of N positive and negative electric charges (±Q i ) constituting a neutral body, as in Figure 7., is given by the sum of products, thus:

M o o i i i= 1-88 - A unification of electrostatic and gravitational forces N = µ ε QV (7.11) where V i is the total potential at the point of location of charge Q i. The gravitational force of attraction F between the body of mass M 1 and another body at R (Figure 7.), of mass M containing N charges (±K i ), is obtained as the product of two sums, thus: N1 N F = M 1M o o QV i i o o Ki Pi û = µ ε µ ε û (7.1) i= 1 j= 1 where is the separation between the bodies, is the gravitational constant and V i and P i are the total potentials at the respective points of locations of the charges Q i and K i. In Figure 7., pairs of opposite charges Q i, of radius a i, separated by distance X i, the total potential V i at the location of charge Q i, is: Q 1 1 i Vi = o ai X i Other potentials at the position of Q i cancel out. Equation (7.11) gives N o 1 1 M = Qi 4 µπ (7.13) i = 1 a i X i Where the constituent electric charges are of the same magnitude Q, same radius a and same separation X, equation (7.13) becomes: N µ o 1 1 µ o NQ 1 1 M = Qi = 4π i= 1 a i X i 4π a X (7.14) Let us find the force of attraction F between the body of mass M 1 and another of mass M at R (Figure 7.). The mass M contains N / pairs of opposite charges, each of magnitude K in the form of a spherical shell of radius b, distance Y apart. Force F is the product: M1M F = û µ N Q o 1 1 1 µ N K o 1 1 û (7.15) 4π a X 4π b Y In equation (7.15), if the charges are in two bodies where 1/X and 1/Y can be neglected compared with 1/a and 1/a, F, is obtained as:

1 µ o 1 1 ζ F M M N N Q K N N Q K = û = = 4π ab û û (7.16) Equation (7.7) and (7.16), giving the gravitational force of attraction as proportional to the product of squares of the charges, are what this paper set out to derive. The electro-gravity constant ζ, incorporating the gravitational constat, is given by: µ o ζ = ab 4π - 89 - A unification of electrostatic and gravitational forces (7.17) 7.7 Deflection of electric fields by an electric charge The attributes of space, of zero electric field (constant potential), inside a spherical electric charge, is different from the attributes of space outside the sphere where the field decreases inversely with square of the distance from the charge. The spherical surface is visualized as a source of energy, a boundary which is tantamount to distortion of a region of space. It creates an electric charge and produces an electric field emanating from the charge and.extending into space to vanish at infinity. The electrid field due to an electric charge is supposed to be deflected or bent when it encounters another electric charge at a point in spsce. The interaction produces a a small deformation of the electric field such that the force of repulsion is slightly decreased and the force of attraction similarly increased. The consequent small decrease in electrostatic energy of electric fields from electric charges composing bodies may account for the gravitational (potential) energy of masses. The effect of deformation of electric fields from charges is gravitational force of attraction between masses in a manner akin to distortion or warping of space, as envisaged by Einstein, but without the time dimension. The space, outside matter in space, is not empty but crisscrossed by electric fields emanating from equal numbers or equal amounts of electric charges composing bodies. The fields are ever present, with the electrostatic forces of repulsion and attraction cancelling out exactly at a point in space, but leaving the gravitational forces of attraction. A gravitational field is present everywhere in space between electric charges composing masses, producing a pull independent of relative velocities between the charges of the bodies.

7.8 Conclusion The import of equations (7.7) and (7.16) is that gravitational force of attraction between masses is electrical in nature, supposed to be the result of deflections of electric fields by electric charges in a body. This explains the force of gravity between masses without recourse to fourdimensional space-time continuum of Einstein s theory of general relativity. It should put to test the idea of four-dimentional space-time and warping of space-time continuum, in the presence of matter, to create gravitation and put to rest the present quest, by physicists [10], for the rand Unified Theory (UT) of everything. We, following the greats, alileo alelei and Isaac Newton, contend that space and time are absolute quantities, independent of the position or motion of the observer and that space is of one dimension, Length, a vector quantity with three orthogonal components. 7.9 References [1] I Newton, (1687); Mathematical Principles of Natural Philosophy (Translated by CAJORI, F., University of California Press, Berkeley (1964). [] A. Einstein & H.A. Lorentz; The Principle of Relativity Matheun, London (193). [3] M. Planck; Ann. Phys, 4 (1901), 533. [4] N. Bohr; Phil. Mag. 6 (1913), 476. [5] L. De Broglie; Ann. Phys. (195), 3,. [6] S. Hawking; A Brief History of Time, Bantam Books, London (1999), chap. 10. [7] B. reene; The Elegant Universe, Vintage, London (1999), chap. 8. [8] J. Barbour; The End of Time, Phoenix, Orion Books Ltd., London (000), Parts II & IV. [9] M.D. Abdullahi; On the Energy and Mass of Electric Charges in a Body, This Book (006), Paper 6. [10]. A. Oyibo; A rand Unified Theorem Representing the Unified Field Theory of Everything, Int. J. Maths., 9 (1999). See author s website: http://www.geocities.com/igala1/new_page_6.htm (006). - 90 - A unification of electrostatic and gravitational forces

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