Mr. Larson has worked. out the static relations between particles in the time region; specifically, he has calculated the equilibrium interatomic distances for all the elements and many compounds (see pages 27-49 of The Structure of the Physlcal Universe). This paper will explore he dynamic relations between particles in the time region.
Consider a particle (say an alpha particle) moving directly towards a stationary atom (say a gold atom fixed in thin foil). Initially the particle has a velocity vo. Once it enters the tlme region, that is, when its distance is less than one natural unit of space, two forces are encountered: the progression and gravitation. In the time region, the progression acts to bring particles closer together, whereas gravitation acts to repel particles — the reverse of gravitation in the time-space region. The progression is stronger until the equilibrium distance is reached, then the gravitational force becomes stronger. I believe that the equation of motion is
| Fp - KG / (xu- x)4 = m d²x / dt² |
(1)
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where
Fp = unit force of the progression
KG = magnitude of the rotatianal motion of the partlcles
xu = natural unit of space
m = mass of the moving particle
x = distance-measured from start of time region
Dividing by m gives
| Fp / m - KG / m (xu - x4 = d²x / dt² |
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The right hand side reduces to
| d²x/dt² = dv/dt = dv/dx dx/dt = v dv/dx |
(2)
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Thus
| Fp/m - KG/m (xu - x)4 = v dv/dx |
Separating variables and integrating, we have
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xf |
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xf |
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vf |
| Fp/m dx - | KG dx/m (xu -x)4 = | vdv | |||
| o | o | vo |
or
| Fp/m xf - KG /3m [(xu - xf)-3 - (xu)-3] = ½ (vf² - vo�) |
(3)
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There are two cases of interest with this equation.
Case 1: Suppose we want to know the initial velocity required to bring the particles to a certain distance apart from each other. Equation (3) is solved for vo, letting vf be zero.
| Vo = (2[KG/3m{(xu - xf)-3 - (xu)-3}-Fp/m xf] )½ |
(4)
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Case 2: Suppose we want to know the final separation between two particles, given vo. Let
| xsep = xu -x |
Equation (3) becomes
| Fp/m (xu - xsep) - KG/3m xsep-3 - xu-3] = ½ (vf² - vo²) |
With vf = 0, and putting the terms irevolving xsep on one side af the equation, we have
| Fp/m xu + KG xu-3/3m + 1/2 vo² = Fp/m xsep + KG/3m xsep-3 |
Define the following coefficients:
| C2 = Fp/m xu + KG xu-3/3m + ½ vo² |
| C2 = Fp/m |
| C3 = KG/3m |
| C4 = -C1/C2 |
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C5 = C3/C2 |
With these coefficients, the result is a quartic equation:
| xsep4 + C4 xsep3 + C5 = 0 |
(5)
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This equation can then be solved by the usual means.
Now, going back to equation (3) we can solve for v as a function of x:
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v = dx/dt = {2[ Fp/m x - KG/3m[(xu - x)-3 -xu-3]] + vo²}½ |
Separating variables and integrating we have
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x | ||
| t = | dx/{2[Fp/m x -KG/3m((xu - x)-3 -xu-3)] + vo²}½ | ||
| o |
The integral can be evaluated numerically by Romberg’s method.
Example
Consider an alpha particle moving directly towards a gold atom in a foil, at an initial velocity of 2.06x107 meters/sec. What is the distance of closest approach? How long does it take to get there? What happens afterward.?
Here we have
vo = 2.06 x 107 m/sec
m = 6.64 x 10-27 kg
xu = .455884 x 10-7 m
Fp = 1.09699 x 10-3 n
Now,
| KG = 1.09699 * 10-3 * (.455884 * 10-7 )4 /(156.44) * ln² tA ln² tB |
For gold, tA =4.5; for helium, tB = 3. But helium has only one active dimension so the force is multiplied by 1/3. Thus
| KG = 1.09699 * 10-3 * (.455884 * 10-7 )4 /(156.44)4 * ln� (4.5) ln� (3) |
| * 1/3 = 7.20006 * 10-42 N-m4 |
(This assumes that since helium is inert, the electric displacements of gold have no bearing on the motion). The coefficients are next calculated:
| C2 = 2.7438094 * 1015 |
| C2 = 1.6520934 * 1023 |
| C3 = 3.614488 * 10-16 |
| C4 = 4.6872709 * 10-8 |
|
C5 = 2.197923 * 10-39 |
The quartic equation is
| xsep4 - 4.6972709 * 10-8 xsep3 + 2.187823 * 10-39 = 0 |
The only physical solution is
| xsep- = 3.6014328 * 10-11 m » .36 Å [3.6226287 * 10-11 m with revised Fp] |
Note that his is cons:lderably greater than that predicted by use of classical atomic theory and Coulomb’s law: 2.581 x 1014 m.
Using equation (6) and Romberg’s method I find that
| t = 6.3041312 * 10-16 sec |
The average velocity of the particle to the point of closest approach is
| 4.552396 * 10-8 /6.3041312 * 10-16 = 7.2212742 * 107 m/sec |
The initial velocity having been dissipated, the particle goes back to the equilibrium point. Of course, at room temperature, helium is a gas, and so the particle would not remain in the time region!
Situations in which the particle is not moving directly towards the atom will be treated in a future paper.