How would you describe the proportional relationship between kinetic energy and mass?
Answers
Answer:
JUST FOUND ON THE NET
Explanation:
The kinetic energy is the existence state of this mass. To be precise, kinetic energy is the movement state of this mass.
Mass is the carrier of this movement. The intrinsic quantity and quality of mass never change. What can be changed is the existence state of mass. Anything happens in the universe is the change in existence state of mass --- from one existence state to another and this process never stop.
Due to the existence state is not coming out of nothing --- it is converted from one form to another, so the total existence state (or say movement state) in the universe cannot change; while due to the natural mechanisms spontaneous adjustment and balancing functions, the total free movement state of mass is dynamically balanced with the position potential state of mass. So the total entropy of the universe is always balanced.
This balance is not mean to be equal in quantity and proportion but the dynamic balance in the transformation of different existence states of mass, so that the general proportion between the positive thermodynamic entropy and the negative thermodynamic entropy are always the same.
More explanation:
In normal conditions, kinetic energy will be used by natural process and human activities and become less and less useful and less and less usable; it will become the locked energy in mass which is the structural and gravitational position potential energy. Only in the extreme conditions in the central black holes, it can be totally converted back into usable form of energy --- free movement state of mass.
The general expression of this relation is:
1. For massive objects (which is the mass state matter that have universal structural energy E = mc² in it )
The kinetic energy of a “massive” object with mass m is KE = mv²/2 or expressed in its general form as E = ∆p*v/2. It means: the kinetic energy of an object is the product of the momentum change and the average rate of this change.
2. For energy state matter (which is the matter that doesn’t have universal structural energy E = mc² in it but depend on its momenta to keep its structure stable and function)
The wholesome mathematical expression of the free movement energy of energy state matter is: when v = c, E = p, p = p vibration + mc, make h c / λ = p vibration, since c / λ = f, h f = p vibration, so E = h f + mc, since ∆E = ∆p vibration, ∆f ∝∆ p vibration, (∆E/∆f) f = p vibration, h = ∆E/∆f. Assume x = compounded movements of p vibration, then mx = p vibration, x = h f / m. E = mx + mc. (12).
From (12), we get:
E = p vibration + mc
E = h f + mc
E = mx + mc
These are the 3 different expressions for the same quantum particle for its mass – energy relations, energy - frequency relations, quantum internal energy distribution.
Note:
For a massive object, its total energy is the sum of its free movement energy (kinetic energy) or gravitational position potential energy and structural position potential energy: E = mc² + ∆p*v/2, or E = mc² + Gm₁m₂/r, or it can be expressed in its momentum form E = mc² + mv, when this v is representing the ideal final velocity to central black hole.
The universe level energy balance (which is constituted by the galaxy level energy dynamic balance) can be illustrated with its momentum expression (due to ∆E∝∆p, and when v = c, E = p) as: ∑ ∆(mc² + mv) = ∑ ∆(mx + mc), (16).
Thermodynamic balance determines all other balances and galaxies are the basic units of the thermodynamic balance that form the overall balance of the universe. The thermodynamic balance reference point is the central black holes of the galaxies where the balance sheet is drawn.