Mathematics for Imagining a Universe

Imagine a Universe contains mere narrative with only oblique reference to equations.  That does not mean that the equations don’t exist.

---

Time (and Space)

The idea I was playing with here was that time slows down as you approach the Schwarzschild radius of a black hole (it actually slows down as you approach any mass, just not as much):

 

t_o/t_f = √(1-2GM/rc²)

 

Where t_o is proper time between two events for an observer at a distance of r from the centre of a mass M, and t_f is co-ordinate time for an observer not under the influence of that mass (strictly speaking not under the influence of any mass).  G is the gravitational constant and c is the speed of light.  Buried in this equation is the Schwarzschild radius r_S = 2GM/c², the event horizon of a non-rotating black hole.

Objects can’t get past this radius, but the narrative suggests that mass/energy (in the form of energy) might – however, when r < r_S, we have a ratio of t_o/t_f that is the square root of a negative number and as r approaches 0, we have a ratio of t_o/t_f that approaches infinity times the square root of a negative number.

While the square root of a negative number is formally called an imaginary number, this type of number is used in a number of fields to denote orthogonality (for example in the use of quaternions) – the notion that two things (electric and magnetic fields, for example) are perpendicular to each other.  Time, as another example, is orthogonal to space.  With the four linked dimensions of spacetime, each is orthogonal to the others.  When, in the narrative, I talk of an orthogonal universe, that universe (notionally) has time that is orthogonal to all the dimensions of this universe and also to the three dimensions space in that universe, each of which in turn is orthogonal to all the dimensions of space in this universe.

There could be no interaction between orthogonal universes, and to each the eternity of the other would be a mere moment – with one at the end, and the other at the beginning.  This permits us to hypothetically link together a chain of effectively eternal universes.

The same logic applies to space due to length contraction as one approaches a mass although it’s not quite as simple, since the length contraction is only in one dimension (parallel to the separation with the centre of the mass).  However, masses that approach the Schwarzschild radius are ripped apart and the resultant energy is smeared across the surface of the black hole – acting as the “reservoir” for the inner universe.

 

Critical Density and Expansion

In cosmology, “critical density” is the density of the universe at which it neither expands forever nor collapses.  Such a universe is described as “spatially flat”.  Critical density is given by:

 

ρ_c = 3H²/8πG

 

where H is the Hubble parameter (note that H₀ is also referred to as the Hubble constant, but that is just the value of the Hubble parameter today) and G is the gravitational constant again.  The Hubble parameter is the rate at which distant objects are receding, given as a ratio between that rate and their distance – usually given in km/s/MPc (kilometres per second per megaparsec).

There is also Hubble time, currently calculated from the measured value of the Hubble parameter – either 67.4 or 74.0 km/sec/Mpc, with errors of about 1-2 km/sec/Mpc (or about 2%) – to be either 13.2 or 14.6 billion years, with error margins of about 0.3 to 0.4 billion years, the mid-range of which is 13.9 ± 0.3 billion years – which entirely covers the range in which the age of the universe lies 13.77 ± 0.059 billion years).

The volume of a “Hubble sphere”, where r_H is the Hubble length (c/H, where c is the speed of light), is

 

V_H = 4πr_H³/3 = 4πc³/3H³

 

The universe appears, very much so, to be spatially flat.  I make the simple assumption that that appearance is reflective of reality.

If the universe is spatially flat, then it always has been and always will be (according to Sean Carroll, who wrote “a spatially flat universe remains spatially flat forever, so this isn’t telling us anything about the universe now; it always has been true, and will remain always true”).  Consider then a “Hubble mass”, M_H, which is the mass inside a Hubble sphere given that the density in that sphere is critical, so

 

ρ_c = M_H/V_H = 3H³M_H/4πc³ = 3H²/8πG

 

So

 

M_H = c³/2HG

 

Recalling that r_H = c/H, and rearranging,

 

r_H = 2GM_H/c²

 

Which is the equation for the Schwarzschild radius of a Schwarzschild black hole of mass M_H.  Note however that there is a direct relationship between the radius of a Hubble volume in a spatially flat universe and the mass contained within that radius.  This means that as the radius increases, so too does the mass, or

 

Δr_H = 2GΔM_H/c²

ΔM_H/Δr_H = c²/2G

 

Another assumption made in Imagine a Universe is that there is a limitation of the rate of expansion to “quantum of length per quantum of time”.  Using Planck units as our notional stand-ins, this would mean one Planck length (L_P) of additional radius per Planck time (t_P), noting that L_P/t_P = c, therefore Δr_H/Δt = c, and thus

 

ΔM_H/Δt = c³/2G = ½c³/G

ΔM_H/Δt = ½m_P/t_P

 

Which means that, within a Hubble volume, mass increases at a rate of half a Planck mass per Planck time to maintain critical density.  (More will be said about this in a later post.)  Note that this does not necessarily mean that the Planck time is the smallest increment of time, merely that even if there are smaller increments, the ratio of mass added per increment will be equivalent to half a Planck mass per Planck time (per Hubble volume).

 

Vacuum Energy and Critical Density

If, as discussed above, mass (or as I prefer, mass-energy) is being added to the universe at the rate of half a Planck mass (equivalent to half a Planck energy) per Planck time (per Hubble volume), then we could work out how much mass-energy would exist in the universe at this time.  At 13.77 billion years old, the universe has experienced 8.06x10⁶⁰ Planck times and so the Hubble volume that we live in would contain 4.03x10⁶⁰ Planck masses, which is 8.77x10⁵²kg.  The currently estimated mass of the observable universe is “at least 1x10⁵³kg”, which is in the ballpark (more on this in a later post).

Note that the energy equivalent of 8.77x10⁵²kg is 7.88x10⁶⁹J, in a Hubble volume of 4πr_H³/3, where r_H is 8.06x10⁶⁰ Planck lengths, so 9.26x10⁷⁸m³.  That makes the energy density 8.51x10^-10J/m³, or ~10^-9J/m³.  Which is the value of vacuum energy.  Converting back into terms of mass, we get 9.47x10^-27kg/m³, or ~10^-26kg/m³.  Which is our universe’s critical density (at this time).  Note the comment here with regard to average density (“including contribution from energy”).

Most of the mass-energy in the universe is sitting there in the vacuum, with only a small proportion manifesting as baryonic matter.

---

The upshot of all this is that if the universe is spatially flat, then the introduction of mass-energy itself would drive expansion of the universe.  It makes sense that this expansion would not be instantaneous – and instantaneous expansion is not what we observe.  What we observe instead is an expansion at a fraction of the speed of light which is proportional to the fraction of a Hubble length that the distant object (usually a galaxy) is from us.  Which is also to say that we live in the centre of a Hubble volume that is expanding at the speed of light (noting that this is not a special place for us, every point in the universe is the centre of its own Hubble volume, some of which overlap without ours).  This in turn means that the universe is expanding at a rate of one Planck length per Planck time (and, as calculated above, increasing in mass-energy at a rate of half a Planck mass per Planck time (per Hubble volume)).

Conversely, if the universe is spatially flat, and the universe is expanding (which we observe), then mass-energy must be being added to the universe.  It’s possible to imagine that mass-energy would be pulled into existence (in our universe) if 1) something else were driving the expansion of the universe while 2) some mechanism was constraining the universe to be spatially flat, noting that this raises the question of where the mass-energy comes from.  But this seems to be a less parsimonious hypothesis.

The far more parsimonious hypothesis is that mass-energy is being added to a spatially flat universe (which is observed) which explains the expansion (that we observe) at the rate at which we observe it, resulting in a density that we observe and a vacuum energy that we observe.  We are then left with only one question – where does that mass-energy come from?

This was the question (to one level) that Imagine a Universe was hinting at.