According to this, while mass and energy might be transformed, the total amount of mass-energy in the universe will not change. |
|
Apply quantitatively the law of conservation of mass and energy, using Einstein's mass-energy equivalence. |
|
Einstein's original derivation of mass-energy equivalence is the best known in this group. |
|
Glaciers, normally the epitome of slowness, can acquire a mass-energy excess and consequently surge. |
|
The cutoff energy represents the mass-energy of the putative dark matter particle. |
|
But the original mass-energy equation still holds, if m in that equation is the relativistic mass, not the rest mass. |
|
The black hole is not consuming space-time, however, it is consuming mass-energy and the increase in the density of mass-energy leads to a change in the space-time curvature. |
|
Now, if curved space-time is needed to give birth to mass-energy and if mass-energy is needed to give birth to curved space-time, which came first, space-time or mass-energy? |
|
Zitterbewegung thus suggests possibly deep connections between zero-point energy and the mass-energy relationship of matter and with the quantum properties of particles. |
|
In a gravity field, the existence of mass-energy determines each element of the space-time curvative, transforms it, and bends space. |
|
Mass-energy conversion occurs during nuclear fusion and fission. |
|