=> m1 = 367 × m2
* Energy of Photons:
E = h × c /λ
Energy of Photons: Usually a stable constant, unchanging and dependent on the type of wavelength.
* Energy of Atoms:
Energy of Atoms: Usually varies according to all physical properties.
We have:
Energy of Photons × Energy of Atoms = 1 (This means they are inversely proportional to each other).
- Gravitational energy (like particle moving energy): It usually increases the mass of the particle.
E = m × ag × s
<=> h × c /λ × M1 × ag × s = 1
<=> λ = (4,88 × 10^-11) × M1
- Particle rest energy: It usually retains the original mass of the particle.
E = M2 × c^2
<=> h × c /λ × (M2 × c^2) = 1
<=> λ = (1,79 × 10^-8) × M2
We have the ratio: Gravitational energy / Particle rest energy (with the same wavelength).
λ = (4,88 × 10^-11) × M1 = (1,79 × 10^-8) × M2
=> M1 = 367 × M2
Therefore, the mass of the moving particle will be increase 367 times compare with the mass of the stationary particle (or particle in a state of rest).
P = M × g (g = 9.81 (m)s^2) is the constant of the gravitational field).
It's similar to P1 = 367 P2 (P1, P2 are creating a gravitational pull with the Earth).
=> This means that if P2 is a constant like a rock (1 kg) lying still on the ground, then P1 is like a meteorite, a meteor, an airplane, with mass of 367 Kg, etc., continuously producing work, which is P1 = M1 × g = 367 × 9.81 = 3600 (J).
Note:
s: is one light years (AU) = 9.460.528.000.000 Km = 9,5 × 10^15 m.
M: is mass of particles include M1 and M2 ( Kg).
+ M1 is the moving mass (Kg)
+ M2 is the resting mass (Kg)
h: is Planck's constant, h = 6.625 × 10^-34 (J.s).
λ: is wavelength (m).
c: is the speed of light, c = 3 × 10^8 (m/s).
ag: Jerk acceleration constant, ag = 0.02582838 (m/s^3), ag = G (The Gravity constant) × ρ(Air) × c (Speed light) = (6,674 × 10^-11) × (1,29) × (3 × 10^8) ( m/s^3).