Tuesday, September 26, 2023

Gravitating mass, inertia, and centripetal acceleration

In general relativity, the gravity potential steepens at low radii r, relative to the newtonian potential.


                       ●  M


                       r


                   m •     
                       |   
                       |   rope
                       | 
                       |   ^
                       |   |  F force
                       |
                         \ o
                            |
                           /\    observer


An observer uses a rope to lower a test mass m very slowly close to a mass M. Let us calculate the potential very naively.

The remaining fraction of the mass-energy of a static test mass is

       sqrt( 1  -   (2 G M / c²) / r ).

The remaining mass-energy is zero at the Schwarzschild radius

       rₛ  =  2 G M / c².

In the newtonian potential, the remaining fraction of mass-energy is

       sqrt( 1  -  (G M / c²) / r ).

It is zero at

       rₛ / 2  =  G M / c².

The horizon radius in the newtonian potential is just 1/2 of the Schwarzschild radius rₛ.


What is the gravitating mass of m?


In the above equations we assumed that the gravitating mass-energy of a test mass m remains m when it is lowered close to M. That is a reasonable assumption if m falls freely toward M and the potential energy which m loses is converted to kinetic energy of m.

But we used a rope to lower the mass m slowly. It did not gain kinetic energy.

The paradox is solved by the fact that the field of M shortens the rope as we lower m downward. The observer can let the force F do work for a surprisingly long additional length of the rope.

The gravitating mass of m and the force F do shrink according to the fraction

       sqrt(...),

but that is compensated by the radial metric stretching according to

       1 / sqrt(...).

The gravity force F shrinks to zero when m is at the horizon.


A perpetuum mobile? No


Let us lower the test mass m in such a way that first it is allowed to gain kinetic energy. After a while, we let it fall at a constant radial coordinate velocity.

The gravitating mass of m is larger than with the slow lowering procedure. Gravity does more work for the whole trip down. Can we recover more energy this way?

No. If we let m fall freely to some distance r from M, its total mass-energy, measured from far away, is still m c². Lowering that mass-energy from the distance r to the horizon will give the energy m c² to the observer – no more.

Energy is conserved. In this context, the notion of "work done by gravity" is misleading.

If we lower the mass m slowly with a rope, we extract the energy from m at larger radii than in the partial free fall case. That is the difference between the two procedures.


The centripetal force and acceleration


To keep a test mass m on an orbit, gravity must give it enough acceleration. The inertia of the test mass m tries to make the test mass to fly along a straight line.


                          ● M
                                       ^ 
                                     /
                      •  ---------
                     m


Thus, the centripetal force is gravity. Crucial in this is what is the inertia of m in this configuration.

We have claimed in this blog that the inertia against a tangential acceleration relative to M is

       m / sqrt(1  -  rₛ / r)

and the inertia against a radial acceleration is

       m / (1  -  rₛ / r).

Which is the relevant inertia on a circular orbit?

Let us look at circular orbits in the Schwarzschild metric.








There μ = m, because we assume that m is very small. The angular velocity ω in the Schwarzschild metric is the same as in newtonian gravity. Is this a coincidence?

If we believe the Schwarzschild metric, then the gravitating mass of m is its total mass-energy, and its inertia on a circular orbit has to be the same, because m stays on the newtonian orbit.

This is strange. The gravitating mass-energy of a static m is

       m sqrt(1  -  rₛ / r).

Can its inertia against the acceleration on a circular orbit be that low?

The acceleration on a circular orbit is neither tangential nor radial. The tangential and the radial velocities stay constant. Thus, the inertia might be that low.

The extra inertia in a tangential motion of m relative to M would be a separate "load" that m has to carry, but that load would "naturally" orbit M so that m does not need to exercise a force to keep the load on a circular orbit. The following mechanical model would explain this:


              <-- ω
              _____      ring of inertia
            /            \
           |      ● M  |  
            \______/
                   • --> v
                  m


When m comes close to M, m attaches itself to a "ring of inertia", which slows down the tangential motion of m. Once m is attached to the ring, the extra inertia does not affect a circular orbit of m. The ring rotates around M at an angular velocity ω without any extra effort.

The extra inertia is a property of the common field of m and M. The inertia is not an independent body which could fly around on its own. It is not strange at all that the extra inertia can stay on a circular orbit without any extra effort from m.

Similarly, the extra inertia does not increase the gravitating mass of m.


The circular orbit of a photon around M


Let us calculate the coordinate radius for a circular orbit of a photon around M.

The tangential velocity of a photon is

       v = c  sqrt(1  -  2 G M / c² * 1 / r).

We have

       G M / r²  =  v² / r
   <=>
       G M  =  v² r

                =  c² r  -  2 G M
   <=>
       r  =  3 G M / c²
  
           =  3/2 rₛ.

If we use a newtonian gravity potential, then

       v  =  c  (1  -  G M / c² * 1 / r),

       G M  =  v² r

                 =  c² r  -  2 G M  +  G² M² / c²  *  1 / r
   <=>
       0  =  c² r²  -  3 G M r  + G² M² / c²
   <=>
       r  =  3/2 G M / c² 

         +- sqrt(9 G² M²  -  4 c² G² M² / c²)  /  (2 c²)

           =  3/2 G M / c²

               +- sqrt(5) / 2 * G M / c².

The sensible value is

      r  =  (3/2 + sqrt(5) / 2)  G M / c²

          =  2.62 G M / c².


Conclusions


The gravitating mass of m close to a mass M is

       m  sqrt(1  -  rₛ / r),

where rₛ = 2 G M / c². The inertia of the gravitating mass alone is the same

       m  sqrt(1  -  rₛ / r).

Also, m feels extra inertia if its tangential velocity or its radial velocity changes. The total inertia of m for a tangential movement is

       m / sqrt(1  -  rₛ / r)

and for a radial movement

       m / (1  -  rₛ / r).

It is not a coincidence that circular orbits in the Schwarzschild metric obey the newtonian equation. The gravity force is newtonian, and the gravitating mass of m is the same as its inertial mass, for a circular motion.

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