In the following, we use a (fuzzy) Minkowski & newtonian gravity model. The speed of light c is the maximum speed of a signal. The gravity force in a static case is as given by Isaac Newton.
Two particles which pull on each other
Let us look at an expansion which is slowing down because of gravity.
particle 1 particle 2
v <--- • --> a a <-- • ---> v
m s m
t₀ time distance
Let us look the process in global "laboratory" coordinates. We have two dust particles flying away from each other. The global time coordinate is t₀.
Gravity decelerates the particles. Because of retardation, the particles "see" each other farther away than they are "currently" in the global coordinates. The gravity is weaker than in the naive model where we would just look at the current distance of the particles.
Also, the gravity field of each particle is squeezed horizontally in the diagram, because of length contraction (Lorentz correction).
Let us calculate how much retardation and the squeezing affects the force of gravity between the two particles. Let us first assume that v << c. Then Lorentz corrections are negligible.
The particle 1 sees the particle 2 as it was the time
t = s / c
earlier. At that time, the particle 2 was receding faster from the particle 1. The particle 1 extrapolates the location of 2 from the velocity of 2 at that earlier time, and sees the gravity field as if 2 were at that extrapolated location.
But the particle is actually "currently" at a location
1/2 a t² = 1/2 a s² / c²
closer. The relative error in the distance is
1/2 a s / c²,
and the relative error in the gravity force is
a s / c².
The force is weaker by that factor than the naively calculated on, using "current" distances.
We conclude that the naive gravity force is replaced with one of the form:
F = G m² / s² - G m² a / (s c²).
The new force formula affects the expansion of the dust ball in a complicated way?
Effect on an expanding dust ball which is largish but not huge
largish dust ball A
radius R
______
/ \
| • m | × center of A
\_______/
B
environment B • m'
of dust particle m dust particle in A
s = distance(m, m')
We have a largish expanding dust ball A and an arbitrary dust particle m inside it. Let B be the largest spherical environment of m, which fits inside A.
We assume that the expansion of A is approximately uniform. Because of symmetry, the net force imposed on m by B is zero. Also, because of symmetry, the retardation of the gravity fields of particles within B has no net effect on m.
The gravity of the set difference
A - B
does pull on m, and the retardation has an effect.
If m is close to the center of A, then all the particles m' in A - B are roughly at the same distance
s ≈ R
from m. The effect of retardation is roughly the same for all m'!
We conclude that the effect of retardation is fairly uniform for any m close to the center.
/ A
/
|O m
\ B • m'
\ Ω
O = environment B of m
Let then m be relatively close to the edge of A. Particles in A - B pull on m.
Let us look at a narrow solid angle Ω whose tip is at m. Most of the pull on m comes from angles which very roughly point to the right from m. The length of the cone determined by Ω from the edge of B to the edge of A is typically
2 s ≈ 1.5 R.
The average distance of the particles m' in the cone, weighted by the gravity of m' on m, is
s ≈ 0.75 R.
We conclude that the effect of retardation is fairly uniform throughout A, with differences of at most +-15% !
If the dust ball is so huge that the "observable universe" is only a tiny part of it
If the test particle m last saw m' receding at almost the speed of light, then m' had a lot of kinetic energy in the frame of m. Also the field of m' is strongly flattened in a way that the force on m is smaller. Which effect wins?
Let us use the analogy from the electric field. The distance in the frame of m' is
~ 1 / sqrt(1 - v² / c²),
and the electric field E strength would be
~ 1 - v² / c².
The "gravity charge" is
~ 1 / sqrt(1 - v² / c²).
This suggests that we can ignore masses m' which are receding very fast from m?
Retardation interpreted in a naive way would break time symmetry of physics
o
/|\ <--- /\/\/\/\
/\
A observer W wave packet
Imagine that a wave packet W approaches an observer A at the speed of light. The observer A is not aware of the gravity field of the packet W because he has not yet received any information about the approaching packet W.
Then the packet W hits the observer A, and is absorbed by his body.
If we reverse time, then in the process, the observer A is aware of the wave packet W that was emitted by his body. Does A feel the gravity field of W now?
We believe that physics is time symmetric. The observer A cannot feel the gravity of W. The gravity field of the wave packet simply cannot extend directly to the front or the back of the packet.
Retardation solves the mystery of why the universe is not frozen, even though it is inside its Schwarzschild radius?
We work in Minkowski space.
Let us make a photon shell to collapse, to form a black hole. The information about the approaching photon shell has not yet reached an observer A inside the shell. Consequently, physics at the location of A will function exactly like before. The proper time of A runs just like the global Minkowski time. There is no "freezing" at A.
The universe looks a lot like this scheme, the time reversed. The matter outside our observable universe is moving away from us very fast.
The universe is not a frozen black hole because no observer has yet received information that the universe is inside its Schwarzschild radius.
If we believe Gauss's law for gravity, then the gravity field of the universe must be immense at its outskirts. The universe would definitely be enclosed inside a black hole. Gauss's law does not hold in this case?
Let us look at a collapse of a very sparse and very large photon cloud. Initially, the cloud is much larger than its Schwarzschild radius. Can any observer know that enough matter at some later time is inside its Schwarzschild radius?
Yes. If the collapse ends into a very compact state, an observer outside the photon cloud will see a very massive compact object. It is a black hole.
However, during the collapse process, no observer inside the photon cloud maybe is aware of this? Then the collapse can proceed without freezing.
Collapse of a photon shell: no gravity felt by photons at all – the end result contains no singularity
We can imagine that the gravity field of a photon is an infinitely thin plane, normal to the velocity vector of the photon. Length contraction has made the field absolutely flat.
In a collapsing spherical photon shell, no photon feels the gravity field of the other photons. The photons can move as if there would be no gravity at all!
An observer outside the photon shell does feel gravity. He may even see that the shell has collapsed into a black hole.
What is the end result of the collapse? As the photons arrive at the center, thy will collide and produce electron-positron pairs. That is, the photons are converted into massive particles. Since massive particles move slowly, the information about the gravity field of the other nearby particles will reach them. A very strong gravity field slows down everything to an enormous degree. The soup of electrons and positrons will "freeze". No singularity is formed. It is just a very dense, essentially frozen soup of particles.
We are able to avoid the formation of a singularity in this model. The end result is a black hole, which has a frozen soup of particles at the center. The Schwarzschild radius may be large, while the radius of the soup is very small.
If we drop an infinitesimal test mass into this black hole, the test mass will freeze at the horizon? The test mass is aware of the huge gravity field of the soup at the center, or is it?
Let us assume that the photon shell was produced by large lasers in a shell structure far away. As the photons converged into the center, their "flat plane" gravity fields were felt by observers outside the shell? Did the observers have time to know that a photon flew by?
Paradox of the gravity field of a photon
laser photon
=== • ---> c
o
/|\
/\
observer
There is a paradox: if the observer is directly below the photon in the diagram, he cannot know that the photon exists. He cannot feel the gravity of the photon. But if he is not directly below, the flattening of the gravity field of the photon prevents the observer from feeling the gravity!
Is it so that a photon does not have a gravity field at all? Could this enable a perpetuum mobile?
The solution to the paradox might be this: before some mass m was converted into a photon in the laser, that mass m did possess a gravity field. Maybe this old gravity field gets updated as the photon flies? In that case, the gravity field of a photon is not a flat plane at all, but is mostly the remnant of the old field of m.
Collapse of a photon shell. Let us look again at the collapsing photon shell. If the photons were created from various masses m, then the old fields of the m's get gradually updated in way that the field "knows" the new location of the mass-energy. The fields will eventually know that the mass-energy is now in the electron-positron soup at the center. Thus, an event horizon forms.
Weakening of gravity comes both from deceleration and flattening of the gravity field from velocity
In the case of an expanding universe or a collapsing dust ball, both retardation from the deceleration, and the flattening of the gravity field, reduce the gravity felt by a test mass inside the system.
Friedmann equations and retardation in Minkowski & newtonian gravity
In the absence of pressure, and a zero cosmological constant Λ, the second Friedmann equation is exactly analogous to a classical newtonian collapse or expansion (classical = the year 1687 version of newtonian mechanics).
Furthermore, we know that the Friedmann equations explain well the observed baryonic acoustic oscillation (sound horizon) phenomena.
Let us interpret this in a collapsing dust ball model. In the classical newtonian version,
1. we can use Newton's shell theorem at the center of the dust ball, and ignore any dust outside the sphere that we are calculating,
or
2. we can use the trick in the second section of this blog post: we look at the gravity of the set difference A - B. We can ignore the gravity of B.
The first is a "local" way to calculate, the second a "global" way. These should yield the same results. Do they yield the same results for retardation, too? If yes, then the shell theorem would hold also for retardation.
However, the formula that we derived in the first section says that the relative retardation correction (in a Minkowski & newtonian model) to the gravity force is
~ a s / c²
~ s².
The relative correction is much smaller in the "local" calculation alternative 1.
We conclude that retardation phenomena gives us information about the entire collapsing dust ball. In cosmology, this means that we get information of the universe outside the observable universe. Dark energy might give us a clue about how large is the entire universe, if the expanding dust ball is defined as "the universe".
Eliminating coupling between particles through retardation: making the particles free
Our example of the collapsing photon shell is an example of a system, where we have been able to eliminate a very strong coupling between particles through retardation.
However, energy has to be conserved. There has to be a mechanism which keeps track of the energy of the system and prevents perpetuum mobiles.
Paradox in the flattening of the gravity field
• <--- ●
m test mass v ≈ c M neutron star
We calculated in a preceding section that the gravity field of an object moving almost at the speed of light is very weak to the direction of the movement. In the diagram we would expect the gravity force of M on m to be weak.
But the field of m does pull M with a very strong force, if we look at the field of m. This is a paradox?
We once again encounter the problem of momentum conservation in a force field.
Calculating the effect of retardation and flattening for a huge dust ball
Let us try to calculate the two effects for a dust ball whose edges are expanding almost at the speed of light, and whose density is close to the "critical density".
The role of the gravity potential is unclear. How to handle it? Clocks tick slower close to the center of the dust ball?
Also, how to handle the stretching of the radial spatial metric?
We believe that slow clocks and length-contracted rulers come from a strong gravity field. If an observer does not yet have the information of that he is surrounded by huge masses that are quite close, then we, maybe, can ignore the change in the metric? It would be similar to the case of the collapsing photon shell.
edge of dust cloud edge of dust cloud
• ---> • <--- •
m' v ≈ c m test mass v ≈ c m''
The expansion of the universe looks uniform and classical newtonian. The particles at the edge of the cloud have gained a very large kinetic energy. The total energy of the cloud has not increased, though. Energy of the gravity field was converted into kinetic energy of particles, especially at the edges of the cloud.
Gravity is pulling a test mass m. Where is the mass-energy of the cloud located?
Hypothesis of mass distribution. The energy of the dust cloud is still uniformly distributed among the dust particles, regardless of the large kinetic energy of the edges of the cloud.
Hypothesis of retardation. If the particles in the cloud are moving at a constant velocity, then the gravity felt by the test mass m pulls it toward the current position of each dust particle m'. "Current" here means a global laboratory time t₀. The field of m' "knows" where m' is located at the current moment.
If the particle m' is in an accelerating motion, then gravity pulls m toward the "calculated" position of m', where the position is calculated based on the last information m can have about the velocity of m'. This is the traditional retardation hypothesis.
| v ≈ c
v
___________
/ \
/ \
| × |
\ /
\____________/
almost all the mass at the edge
Exponentially dense outer shells. Let us try to describe the dust ball in the frame of the center. If a particle at a distance r is approaching at a velocity 0.9 c, then a particle at a distance approaches at 0.99 c, and so on. Length contraction makes the shells at radii
n r ... (n + 1) r
exponentially thinner. At the center is a dust ball where the velocities are nonrelativistic. Let its radius be R. The entire huge dust ball has a radius which is only a few times R, say, 3 R.
Almost all the huge mass is close to the radius 3 R, and approaching, say, at a velocity (1 - 0.1¹⁰⁰) c.
We should find a reason why this system roughly satisfies Newton's shell theorem, but not entirely, because of retardation.
A r = distance(A, B) B
• • • • •
<- 0.99 c <- 0.9 c 0.9 c -> 0.99 c ->
The diagram above is drawn in comoving coordinates of dust particles •, but the velocities are in the frame of the mid particle. Is there some reason why we should claim that the gravity force which A exerts on B is
F = G m * m / r²,
where m is the (rest) mass of each particle, and r is their distance in the comoving coordinates?
If the velocities were slow, then it would be the newtonian gravity formula. But now we are dealing with velocities ≈ c, and extreme length contraction in the frame of the mid particle.
Two particles once again
<--- F
============ ruler --> v
• -> a • --> v
m m'
============ ruler
r
Let us assume that the acceleration of m is
a = G m' / r² * γ, (1)
where
γ = 1 / sqrt(1 - v² / c²).
Let us Lorentz transform a to the comoving frame of m'. Do we obtain consistent results?
In this case, ux = 0, and we have denoted γv by plain γ. We have
a' = G m' / r² * 1 / γ². (2)
In the comoving frame of the m', m is at a (moving) ruler position r γ. The result would be consistent if m would not be moving fast, at the velocity -v in the moving frame. But if v is large, the acceleration is much less. Our assumption was wrong.
Let us assume that the gravity force on m in the moving frame is F'. We calculate the acceleration a' of m in the moving frame. It depends on the inertia of m.
If m would be flying in empty space, the momentum would be
p = v m / sqrt(1 - v² / c²).
(But m is inside the gravity field of m'. The inertia of m may be different.) Let us calculate the "inertial mass":
dp / dv = m / sqrt(1 - v² / c²)
+ v m
* -1/2 (1 - v² / c²)^-3/2
* -2 v / c²
= m / sqrt(1 - v² / c²)
* (1 + (v² / c²) / (1 - v² / c²)).
For v² / c² << 1, we can ignore the second summand above, and
dp / dv = γ m.
Then the formula (1) above is consistent with (2). The "inertial mass" is the same as the gravitating mass.
But we are interested in cases where v² / c² ≈ 1. For v² / c² ≈ 1, we have:
dp / dv ≈ γ³ m.
The "inertial mass" is larger than the gravitating mass, which is only γ m.
Let us assume that in this case, the "active gravitating mass" (the active mass pulls other masses) for a very fast particle is m' / γ:
a = G m' / r² * 1 / γ,
a' = G m' / r² * 1 / γ⁴.
In the moving frame, the distance is γ r, and the "inertial mass" of m is γ² its "passive gravitational mass" (passive mass pulls m toward other masses). We get the same value for a'. This agrees with our calculation in an earlier section where we used the analogy between gravity and an electric field E. However, we have so far ignored the fact that m and m' are immersed in a gravity field. That may change the inertial masses.
*** WORK IN PROGRESS ***
