Aether Science

The Physics of the Aether — Research by Harold Aspden

Appendix I — Physics Without Einstein (1969)

A three-light-year-tall pillar of gas and dust in the Carina Nebula, photographed by the Hubble Space Telescope for its 20th anniversary
Three-light-year-tall star-forming pillar in the Carina Nebula. Credit: NASA, ESA and M. Livio — Hubble 20th Anniversary Team (STScI) · NASA Image Library ↗

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APPENDIX |

Electrostatic Energy and Magnetic Moment of Spinning Charge

Consider a sphere of radius @ containing an electric charge e. The charge distribution within this sphere is determined by the condition of uniform pressure. The electric charge has an intrinsic mutual repulsion and it is constrained against the action of such internal forces to occupy the limited volume of the sphere. Pressure has to be uniform inside this charge. The charge distribution must be radial due to symmetry. Within any spherical shell concentric with the centre of the sphere the charge distribution is uniform over the solid angle subtended. Thus, if ey denotes the charge contained within radius x and de, is the charge in the shell of radial thickness dx, we may calculate the outward repulsive force due to their interaction as e,de,/x* from Coulomb’s law. This is the force differential across the shell and it must equal the pressure, denoted P, multiplied by an increment in surface area across the shell. This is the differential of 4nx* or 82xdx. From the equality:

82Px8dx =e de, (1) Since P is constant, it follows from this that: 4nPx?d(x*) = exde, (2) whence: Cy =NX24/4nP (3) This gives: P=e/4na! (4)

From (3), the electric field intensity e,/x2 within the charge may be shown to be constant and equal to 1/4zP. The internal electrostatic energy of the charge is then found by multiplying its volume 4za3/3 by this field intensity squared and dividing by 8z. The energy E’ is then:

E’ =2na°P/3 (5)

210 PHYSICS WITHOUT EINSTEIN

From (4) and (5) this is simply e?/6a. This is to be added to the well- known value of the field energy outside the charge radius of e?/2a to obtain the total electrostatic energy E of the charge given as:

E=2e?/3a (6)

It is to be noted that the charge must adopt spherical form because it would otherwise occupy the same volume and have a higher electrostatic energy. It is the contention of the theory presented in this work that space is strictly quantized. The volume available for the charge e is limited. According to this volume, the energy of the particle is determined on the assumption that it is a minimum. Thus, taking the spherical form as reference, imagine an element of charge to be pushed out to distort the sphere at some point. Then elsewhere an element of charge must receed inwards to keep the occupied vol- ume constant. Electrostatic energy is decreased less for the outward displaced element than it is increased for the inward displaced one. As a result, minimum energy means a spherical charge. This facilitates spin about an axis through the centre of the charge sphere, since rotation about this axis can occur without disturbing the medium outside the sphere containing the charge.

By differentiating (3) with respect to x and dividing by the volume of a spherical shell 472x2dx, it can be shown that the charge density within the sphere of charge varies inversely with distance from the charge centre. The charge de, of the shell is 2x/4z2P dx, so, noting that the velocity moment of a spherical shell is } times its radius squared per unit angular velocity, the magnetic moment of the charge e becomes:

a 3 | gx22x4/4nP dx (7) oO or: ai &e V4nP w (8)

«) denotes angular velocity. To explain the parameter 2c, remember that the magnetic moment of unit electromagnetic charge is 47 times its velocity moment times its frequency of rotation, 1/22 per unit angular velocity. From (4) and (8), the magnetic moment of the charge e is: eau

6c (9)