The Vacuum Energy Fractal, the Amazing Quantum Vacuum

 

En este post nos valemos de matemáticas elementales y un nuevo planteamiento para estudiar las propiedades de la energía del vacío como un simple fractal. Descubrimos las posibles dimensiones compactadas de la teoría de cuerdas y su importancia en la propia naturaleza del cuanto de acción (en muchas entradas de este blog, podeís leerlo en español, y en la referencia final de la Universidad de Puebla, México, o en Mi_ciencia_abierta).

Abstract

 

In this letter, we use elementary mathematics and a novel approach to study the properties of vacuum energy as a simple fractal. By applying fractal geometry, we can identify the compact dimensions and gain a better understanding of their significance in the fundamental nature of quantum action.

Keywords: Vacuum energy, compacted dimensions, relative fractal dimension, transition of dimensions, hypothetical quantum generalization

1 Introduction

 

The existence of Planck's quantum of action transforms Newton's classical and deterministic universe into a quantum universe, governed by Heisenberg's uncertainty principle. The vacuum contains a zero-point energy (ZPE) with a higher value as the distance considered becomes smaller. The minimum length, known as Planck's length (lp), is associated with a maximum energy called Planck's energy (Ep). For a distance n(lp), the associated energy is (Ep)/n, where "n" is a natural number. This property, conserved across all known scales, will assist us in analyzing this fractal. We will see that the relationship between ordinary dimensions and compact dimensions may have played an essential role in Planck’s quantum of action.

 

 2 Fractal dimension, study of Brownian motion and the Koch snowflake

 

Fractal dimension is composed of two components: the topological dimension and a dimensional coefficient (topol_dim + dimens_coef). The more irregular the fractal, the higher the dimensional coefficient. For the purposes of our study, it is particularly interesting to examine simple fractals that possess a topological dimension of 1, such as the fractal path of Brownian motion.

 Brownian motion (also known as Brownian movement) refers to various physical phenomena characterized by small, random fluctuations in some quantity. It was named after the Scottish botanist Robert Brown, who first studied these fluctuations in 1827 (britannica.com, December 23, 2021).

Top of Form

To move N effective steps in a straight line along one dimension, a particle moving with Brownian motion must take N² total steps across two or more dimensions. The fractal dimension, a basic property of fractal lines [1], can be calculated using the relation log(N²) / log(N) = 2. In this case, the topological dimension is 1 and the dimensional coefficient is also 1. The value of 2 for the fractal dimension indicates that a linear movement, of topological dimension 1, can fill a plane of topological dimension 2.

In Brownian motion, and in general, fractal value = N² = distance^{fractal_dimension}.

 This can also be observed in the Koch curve, as shown in Figure 1. In the first iteration, the side that measures 3 segments becomes 4 segments. The fractal dimension is calculated as log 4 / log 3 = 1.26186. In one dimension, 3 segments become 4 segments in two dimensions (the plane):4= 3^1,26186, 4=3^{fractal_dimension} (Mandelbrot, 1987).

 

 

 3 Fractal dimension of vacuum energy

 

 We know the dependence of vacuum energy on distance:

 En = Ep / n = (Ep) (distance)^-1.

 If we live in hyperspace (according to string theory), we know the dependence of vacuum energy on distance in that space. Let En_(hyper) be the value of the energy in hyperspace. Then:

 log (En_(hyper)) / log (En) = -1

This implies that vacuum energy is proportional to distance in hyperspace. Although energy has no topological dimension of 1, the quotient of the two logarithms behaves similarly to the case of Brownian motion. When comparing two energies, the topological dimension no longer matters because the result is a relative fractal dimension:

 Relative fractal dimension = (topol_dim. + dimens_coef.)/(topol_dim.). To simplify we will write:

 Relat_fr_dim. = (δ+ε)/δ (1).

 So, we have: Relat_fr_dim= Log (En_(hyper)) / log (En)= -1 = (δ+ε)/δ.

The -1 value reminds us of the compacted dimensions of the string theory, since while a positive dimensional coefficient indicates that the fractal occupies a space greater than its topological dimension, a negative dimensional coefficient indicates dimension compaction (Ruiz-Fargueta, 2004). The situation indicates a transition of dimensions such that: 

T:  δ àδ−ε.

 

The expression (1), with this transition becomes:   δ/(δ−ε) (2).

If the dimensional coefficient is the same as the number of compact dimensions.

 

Expression (2) is consistent with the value -1, since for d = 3 it gives us the value -6 for the number of compact dimensions, which coincides with the value predicted by string theory. Applying these values ​​to the expression (1):

 

(δ+ε) / δ = (3+6)/3= 3 .  3  is the relative fractal dimension of the vacuum energy, 9 its true fractal dimension.

 

The same result is found in the following equivalent transformations:

T1₁: 1/n→ n }  log(n)/log(1/n) = -1. Apparent result in relative fractal dimension.

 T1₂:  n→ n³  }   log(n³)/log(n) = 3. True result in relative fractal dimension.

 

The T1₁ transformation gives us the apparent result -1. But the transformation T1₂ gives us the true result 3.

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 4 Generalization and possible transition of dimensions

 

The value -1 is the result of En, as a function of distance, in the expression

(En)(n) <Constant, where we have replaced the time (energy-time uncertainty principle) by the space (n) traveled by the light in that time. If in this expression we add a fictitious coefficient f, we will have:

  (En) (n^f) <Constant    (3) (Hypothetical quantum generalization)

Now the transformations T1₁ and T1₂ will be:

 T1₁: 1/n^f à  n } 

 T1₂:  n  à  n^2+f  }

 The true generalized result of the relative fractal dimension is

log(n^2+f)/log(n) = 2+f, with the expression (1):  (δ+ε)/δ = 2+f    (4)   

 During the transition of dimensions, the value of the fictitious coefficient f, associated with the very nature of the quantum (hypothetically), was defined. We will analyze the transition of dimensions combining expressions (3) and (4), for ε=9−δ:

 (En)(n^(ε−δ)/δ) <Constant. 

 Multiplying and dividing by n^δ which is the generalized volume to ordinary dimensions δ:

 (Energy_density) (n^φ)<Constant.  The value of φ = (δ²−2δ+9)/δ and is represented in figure 2.

 

 

 For δ = 3 there is a minimum that corresponds to a maximum in energy density. For δ = 0, the value is infinite and corresponds to a minimum density equal to zero. The transition of dimensions from δ = 0, ordinary dimensions, to δ = 3, ordinary dimensions, takes us from a vacuum energy equal to zero to a maximum value. “In particular, our laws of physics arise from the geometry of the extra dimensions. Understanding this geometry ties string theory to some of the most interesting questions in modern mathematics, and has shed new light on them, such as mirror symmetry” (Polchinski, 2015)

 

 

5 Conclusion

 

It is possible that there was a transition of dimensions that maximized the energy density of the vacuum for δ=3 (ordinary dimensions) and ε=6 (compact dimensions). The nature of the quantum of action may be tied to these specific values of δ and ε.

 

  

References

 

 Mandelbrot, B. (1987), Los objetos fractales, Barcelona, Tusquets Editores.

 Polchinski, J. (2015), String theory to the rescue. ArXiv: 1512.02477 v5 [hep-th]

 Ruiz-Fargueta, J.S. (2004) El sorprendente vacío cuántico. Revista Elementos Universidad de Puebla BUAP.MX, 53, pp.52-53. (16/01/2022)https://elementos.buap.mx/directus/storage/uploads/00000002608.pdf