We previously revealed a quantitative relation by which the fine-structure constant α can be described by the temperature T of cosmic microwave background (CMB) with several other fundamental constants, including the elementary charge e, the Boltzmann constant k, the Planck constant h, and the light of speed in vacuum c. Given that the value of α is quite conserved but T is variable across CMBs, we propose that c changes with T and can be given by T, the present CMB temperature T 0 and the present light speed c 0. As T is continuously decreasing, c is thus predicted to decrease at a rate of ~2.15 centimeters/second (cm/s) per year. Moreover, we provide a lot of evidence to support this finding. In conclusion, this study suggests a possibility of variable speed of light in vacuum.
Light in vacuum always travels at the constant speed, which is one of the key insights of relativity theory and modern physics. Given the big success of relativity theory in many areas, it is widely accepted that speed of light in vacuum c is a constant of our nature, and thus, it is no surprise that its value has not been measured for ~40 years since the latest measurement (299,792,458 meters/second, m/s) by National Bureau of Standards in 1983 [
We previously revealed that the fine-structure constant α can be precisely described by the temperature T (or expected average frequency f) of cosmic microwave background (CMB) as the following equation [
{ α = β e 2 f h c α = β e 2 k T h 2 c (1)
where e is the elementary charge, k is the Boltzmann constant, h is the Planck constant, and c is the light of speed in vacuum. β is 1 kg∙m3∙s−1∙Coulomb−2, which was introduced to make the dimension consistence. In addition, it is important to give a physical reason for the introduction of β. It is known that α is a constant, and e, k, h, and c are also constants but T is variable across CMBs. That is, changing T should result in variation of α. Strikingly, however, it was recently reported that the measured value of α is quite stable along the observed-scale of space-time and temperature of CMBs [
c T = T T 0 c 0 (2)
where c0 is the speed of light in vacuum at present CMB (that is, at the present space-time, c0 = 299,792,458 m/s). As our universe is continuously cooling, the speed of light in vacuum thus could be timely decreasing along the temperature T of CMB. It is known that the cosmic redshift z is defined as
z = ∇ f f T = f 0 − f T f T = v c 0 (3)
where fT is the expected average frequency of CMB at temperature T and v is the recession velocity of one given galaxy. It should be noted here that CMB frequency is related to the CMB temperature but not frequency of light emitted by a galaxy. In addition, because the Hubble constant and recession velocity are both calculated based on c0, it also should be noted that the speed of light in vacuum of Equation (3) is c0 but not the speed of light in vacuum at other space-time (e.g. cT). Moreover, it is known that the Hubble constant is around H = 70 km/s/Mpc [
z = ∇ f f T = T 0 − T T = v c 0 (4)
Then, the temperature T of CMB after ~3.26 million years will be T = 0.9997666T0. Then, the speed of light in vacuum at that space-time (T = 0.9997666T0) will be
c T = T T 0 c 0 = 0.9997666 c 0 (5)
Given the above observations, it is not difficult to obtain that currently the speed of light in vacuum decreases as the following rate:
c 0 − c T 3261563.7771674528 = 2.15 cm / s per year
Here we use c0 = 299,792 km/s and v = 70 km/s. As a result, we predict the speed of light in vacuum to decrease at a rate of ~2.15 cm/s per year.
In the above section, we infer a variable speed of light in vacuum and find that the speed of light in vacuum decreases at a rate of ~2.15 cm/s per year at present space-time. Although it seems unbelievable that the speed of light in vacuum is variable, we try to present some clues to confirm this finding. As the speed of light in vacuum has not been measured for ~40 years, we have to find some other evidence to support this finding, as follows.
We noted that the total CMB energy in a space (e.g. Earth-Moon system) at CMB temperature T can be given by
E T = k T ( 4 3 π r 3 ) (4)
where 4πr3/3 is the volume of the sphere with a radius of r (e.g. the Earth-Moon distance, 3.844 × 108 meters). Based on the law of conservation of energy, that is, ET = ET0, we can obtain the following equation,
4 3 π k T r T 3 = 4 3 π k T 0 r T 0 3 (5)
As a result, according to the Hubble’s law and Hubble constant (70 km/s/Mpc), it is not difficult to predict that the recession rate of Moon from Earth is 0.92 centimeters per year (0.92 cm/yr), which is quite close to the value (1.24 ± 0.71 cm/yr) derived from the analysis of sedimentary cyclic rhythmites of tidal origin [
As the speed of light c continuously decreases, it is thus expected that equal numbers of photons from Sun will produce less and less energy on Earth. As a result, the temperature of the Earth system is expected to continuously decrease although it may increase at some time scale due to some reasons like volcano. Indeed, it was reported that the temperature of phanerozoic oceans do globally decrease as time by the measurement of oxygen isotopes [
Besides the above evidence, we also have some evidence from thought experiments.
Firstly, according to Equation (2), the speed of light in vacuum c will be bigger/smaller at a space-time with higher/lower T. Thus, c would be zero when T decreases to 0 K in a future space-time according to this study, however, c is constant in classical theory. We think that in a zero temperature of CMB, a zero speed of light in vacuum is more reasonable than a constant one, that is, c0 = 299,792,458 m/s. But a universe with 0 K CMB would be another singularity opposite with the one before the Big Bang.
Secondly, according to the Big Bang theory, our universe comes from a singularity, which is a dimensionless point where all the mass of the universe concentrated. It seems quite bizarre for such a huge mass of our universe concentrated in such a small dimensionless point. Current physics cannot explain it well. According to our finding, the mass-energy equation E = mc2 should be re-written as
E T = m c T 2 = m T 2 T 0 2 c 0 2 (6)
| Methods | With (true) | Without |
|---|---|---|
| This paper | 0.92 | 3.68 |
| SCRT | 1.24 ± 0.71 | 4.00 ± 0.71 |
| NASA | 1.04 | 3.80 |
where m is the mass of the object and ET is the equivalent kinetic energy of the object at temperature of CMB T. According to the conservation law of energy, the total energy in our universe should be conserved. Using the new mass-energy Equation (6), it is thus not difficult to predict the mass of universe at the singularity. The temperature of our universe at the Planck time was estimated to be ~100 million trillion trillion (Tp = ~1032) Kelvins [
{ E = E 0 = m 0 c 0 2 E = E p = m p c p 2 = m p ( T p T 0 c 0 ) 2 (7)
As a result, the mass of our universe at the Planck time (almost the time in singularity) is predicted to be mp = ~1.438 × 10−3 kg. That is, the mass of our universe around the Big Bang singularity is only ~1.438 gram, which is thus much more reasonable.
Thirdly, according to relativity theory, nothing can move faster than light. However, it was observed that there are indeed something moving faster than light, e.g. universe expansion and jets of material moving away from the black hole [
In summary, we have revealed and quantified the relation of the temperature T of cosmic microwave background (CMB) with the speed of light in vacuum. As T is variable, we suggest a possibility of variable speed of light in vacuum and predicted it to decrease at a rate of 2.15 cm/s per year at present space-time. It should be noted that the definition of meter is based on the measured value (c = 299,792,458 m/s) of speed of light in vacuum by the National Bureau of Standards in 1983. What we proposed in this paper is a possibility of variable speed of light in vacuum across space-time. A personal definition of meter by the speed of light in vacuum at that space-time (Earth in 1983) does not conflict with different speeds of light in vacuum at other space-time. Moreover, we provide a lot of evidence to support variable speed of light in vacuum. It should be noted that in a given specific space-time, the speed of light is the maximum speed, which is still consistent with the relative theory. What we revealed in this study is that in different space-time (that is, different CMB temperatures), the speed of light would vary as CMB temperature T. The definition of the speed of light is the speed at which light travels in a vacuum. Both Maxwell’s theory and relative theory take it as a constant as it is determined by vacuum permittivity and vacuum permeability, which were both considered to be constant. It is well known that c 0 = 1 / ε 0 μ 0 and vacuum permittivity and vacuum permeability are constant, however, which should be in the same space-time. According to our finding, different space-time should have different values of vacuum permittivity and vacuum permeability, and thus different speeds of light. We previously inferred that
vacuum permittivity ε 0 = 1 2 f [
With the continuously cooling and expansion of our universe, the vacuum will become more and more ‘bare’, and thus the speed of light in the universe at different space-time will be quite different from c0, which matches Dicke’s opinion well [
However, more evidence, especially direct high-precise measurement of the speed of light under the same condition across years (or one year), is required to support the above findings. In addition, some indirect measurements may be also helpful. For example, according to Equation (2), the gravitational force and the gravitational constant G in our previous study [
F T = γ k 3 T 2 T 0 2 π c 0 h 2 M m r 2 (8)
G T = γ k 3 T 2 T 0 2 π c 0 h 2 (9)
where γ is 1 unit m3∙kg3∙s−1, which was introduced to make the dimension consistence. That is, the gravitational constant G is also predicted to be decreasing as time. Very recently, Brack et al. at ETH Zurich had measured 13 values of G on Mar-2021 and 5 values of G on Apr-2021 [
indeed decreasing. However, this measurement is in a short period and a small number of samples, continuous large-scale and high-precise measurements [
The author declares no conflicts of interest regarding the publication of this paper.
Cui, Q.H. (2022) On the Possibility of Variable Speed of Light in Vacuum. Journal of High Energy Physics, Gravitation and Cosmology, 8, 927-934. https://doi.org/10.4236/jhepgc.2022.84063