1. Introduction
It is well known since the 1930s, that the observed rotational velocity of matter and energy in the outer arms of flat spiral (disc) galaxies, such as our own Milky Way galaxy, is greater than that predicted by the inverse square law of Newton’s law of universal gravitation (1729). This mysterious phenomenon suggests, in general, that the visible (Newtonian) mass of a flat spiral galaxy alone cannot be the total source of the gravitational force holding a massive system of stars, planets, gas, and dust together.
Generally, a parcel of energy produces a gravitational field. Hypothetical massless quanta of the gravitational field are called gravitons [1], and their energy, such as photons, which are quanta of the electromagnetic field1 generate packets of coherent temporal oscillations within the Planck lattice [2] [3]. However, because gravitons are essentially particles of spacetime itself, then unlike photons, gravitons not only travel at the speed of light but also oscillate along with the internal oscillations of the Planck lattice. As is known from Maxwell’s work on electromagnetism, a moving electric charge radiates electromagnetic waves. Similarly, Einstein’s work on gravity showed that a moving gravitational charge radiates a gravitational wave. Thus, we imagine an empty space near parcels (or distributions) of energy to be full of gravitons jiggling about, coupled to localized standing waves of the Planck lattice. Suppose that each standing wave mode of curved spacetime is coupled to a graviton that oscillates at the same frequency as the standing wave. Each graviton has two degrees of freedom, one for kinetic energy and one for potential energy, so it has an average energy of kBT according to the equipartition theorem. In thermal equilibrium, the average oscillation energy of the graviton and the standing wave mode of curved spacetime must be the same for the two to be in thermal equilibrium. Hence, each mode of oscillation of the gravitational field has an energy kBT and can be considered as having a temperature T, which is the basis of the Rayleigh-Jeans theory (1900) for the spectral radiance of electromagnetic radiation.
2. Rotation Curves of Spiral Galaxies
As in the case of oscillating electrons in a material radiating electromagnetic energy, we have oscillating gravitons radiating gravitational energy in a similar manner. Because oscillating gravitons increase the energy of a gravitational field, which increases the frequency of graviton oscillations, the resulting strength (or energy) of any gravitational field should be infinite. However, this does not agree with the observations. Therefore, we propose that the gravitational energy spectrum be discrete. In accordance with Planck’s (black-body) radiation law [4], which has proven to be adequate thus far, we conjecture that for a given increase in the curvature of spacetime, the oscillation frequency of the gravitons may increase if the increase in the gravitational field energy is greater than or equal to the fundamental unit of energy, as defined by the Planck-Einstein relation, for that particular frequency. This assumption is essential to prevent the energy of the gravitational field from becoming infinite.
Now, we proceed under the general assumption that the gravitational field of a spiral galaxy consists of a familiar classical Newtonian component
that includes all forms of matter and energy that are not made of spacetime, and a hypothetical gravitational black-body radiation (GBR) component
, which is due to the (finite) energy of the oscillating gravitons of a Newtonian gravitational field. The GBR component of the gravitational field is presumed to be vanishingly small, except in the case of large mass-energy2 distributions such as galaxies or clusters of galaxies. Therefore, in general, the gravitational field
of an arbitrary energy distribution is defined by the following expression:
. (1)
Let us assume that the radiation energy
produced by the Newtonian gravitational field of a spiral galaxy is equivalent to the difference in kinetic energy between the observed (empirical) rotation speed and the Newtonian rotation speed. Thus, we may write
, (2)
where
is the visible (Newtonian) relativistic mass of the system,
is the relativistic mass of the GBR, v is the observed rotational speed of the galaxy, and
is the rotational speed of the galaxy, as predicted by Newton’s law of gravity for a spherical (symmetric) energy distribution. It follows that the rotational velocity of the system is suitably determined by
, (3)
where r is the radial distance from the center of rotation of the system,
is the Schwarzschild radius of the Newtonian gravitational source, and G is Newton’s universal gravitational constant.
From the equation for circular motion, we obtain an expression for the gravitational field, as follows:
, (4)
which gives
. (5)
Hence, the Newtonian and GBR components of the gravitational field are, respectively:
and
. (6)
From the famous radiation law of Max Planck (1900), the relation for the spectral density of an electromagnetic black body in thermal equilibrium is given by:
. (7)
Hence, with some foresight, we presume that, in general, the radial distribution of the GBR energy density of a spiral galaxy has the following form:
. (8)
The constant parameters A and B are to be determined such that the computed rotation speed of the galaxy due to the energy density distribution of the GBR, as prescribed by the relation above, equals the observed rotation speed of the galaxy
, (9)
which corresponds to the expression developed earlier. The values of A and B were computed for a few example galaxies and are listed in Table 1.
The GBR energy is related to the energy density by the following equation:
, (10)
where
is the approximate volume of empty (interstellar) space, as determined from the Newtonian (non-gravitational) energy content3 of the galaxy;
is the total volume of a disc with radius r and approximate average thickness
, and
is the total gravitational energy of the system, as determined from the rotational speed v of the system.
Note: The values for A and B were determined from observational rotation curve data provided in Refs. [5] [6]. The approximate average thickness of the galactic disc
is determined by scaling the thickness to diameter ratio of the Milky Way by the ratio of maximum angular speed of the Milky Way to the maximum angular speed of a given spiral galaxy, that is,
, where
and
are the usual relations for angular speed and radius of a rotating object, respectively. This relationship suggests in general, that as the angular velocity of a rotating system increases, it tends to spread out, which causes its thickness to diameter ratio to decrease.
From these relations, it immediately follows that
. (11)
Applying these theoretical considerations to the Milky Way, one can readily observe that as the volume of space filled with GBR increases, the number of allowed energy states increases as well, which increases the gravitational radiation component of the interstellar gravitational field and subsequently causes the rotation curve of the Milky Way to flatten4. Although this empirical result manifestly contradicts the “behavior” of the typical rotation curve as predicted by Newton’s well-known classical theory of gravitation, it is in complete agreement with the predictions of our nonclassical (Planckian) theory of gravity as presented here in this paper.
By differentiating
with respect to r, to find the location
of the maximum energy density, we obtain the following equation:
, (12)
which can be iteratively solved. After a few iterations, we obtain the following simple equation:
. (13)
Once B is determined from observational (rotation curve) data, it is straightforward to compute the location of the peak energy density of the GBR distribution. We found that the peak energy density of the GBR of the Milky Way is approximately 4.28 nJ/m3 and is located 3.72 kpc from the center of the galaxy, as illustrated in Figure 1.
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Figure 1. The rotation curves of four spiral galaxies calculated by assuming the gravitons of the local Newtonian gravitational field oscillate and radiate thermal gravitational energy. The Newtonian rotation curve for light traces mass is shown by the dashed line, and the rotation curve observed in the 21-cm line of neutral hydrogen is shown by the solid line, which extends far beyond the bright galactic center. The squares lie along the theoretical rotation curve of the galaxy due to GBR, and the dotted (short dashed) curve is the corresponding GBR energy density profile. The theoretical rotation speeds agree well with the observational (experimental) data5.
3. Black-Body Temperature of Curved Spacetime
The GBR of a spiral galaxy consists of gravitational radiation in thermal equilibrium with the interstellar gravitational field. When they are in thermal equilibrium, the average rate of emission of radiation by the gravitational field equals the average rate of absorption of gravitational radiation. At thermal equilibrium, the temperature of the interstellar gravitational field is equal to the temperature of the radiation, which consists of gravitationally charged gravitons oscillating in phase along the local time coordinate axis of the corresponding unit cells of the Planck lattice [3].
Hawking radiation (1974) is caused by the energy fluctuations of the quantum vacuum near the event horizon of a black hole. In general, the oscillating gravitons of GBR are harmonic temporal fluctuations of the Planck lattice near a massive body; therefore, let us suppose that the thermal equilibrium (black-body) temperature T of the GBR and the gravitational field (curved spacetime) follows from Hawking’s radiation formula:
, (14)
where TH is the Hawking temperature [9] and A is the equilibrium energy6 of the GBR for the mass distribution under consideration. It follows from Table 1, that the blackbody temperature of the Milky Way’s gravitational field is 0.29 pK.
By equating the exponents in the denominators of equations
and
for electromagnetic and gravitational blackbody radiation, respectively, we obtain:
. (15)
Since
, the GBR energy density
may be written as
, (16)
where
is the Hawking wavelength,
is the ratio of the equilibrium energy density of the radiation to the kinetic or Hawking energy density of the oscillating gravitons,
is the number of states per unit volume, and the average energy per “mode” or “quantum” is given by
, (17)
where
is the energy of the quantum and
is the Bose-Einstein distribution function, which provides the probability that a given energy level will be occupied.
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Figure 2. The spectral density of gravitational radiation emitted by the Milky Way galaxy. The energy of the GBR emitted by the interstellar Newtonian gravitational field of the Milky Way near Earth is estimated to be slightly over twenty trillion (~1013) times smaller than the lowest frequency (~300 GHz) of electromagnetic radiation emitted by the Sun, which is approximately 750 times smaller than the lowest frequency (~10 Hz) that can be detected by LIGO7 [10].
In general, the GBR spectral energy density, which is plotted in Figure 2 for the Milky Way galaxy, has the form.
, (18)
where
is the density of states per unit wavelength. Similar to electromagnetic black-body radiation, the total energy density for GBR
, (19)
is finite and proportional to the equilibrium energy density of the radiation
, (20)
which, according to the data provided in Table 1, gives us a value of 0.107 nJ/m3 for the equilibrium energy density of the GBR in the Milky way [11].
4. Interesting Theoretical Results
The distance R from the Earth to the Moon is approximately 3.84 × 108 m. The computed energy density of the GBR that fills the empty space throughout the Solar System is approximately8 2.63 nJ/m3. The strength of the gravitational field produced by local interstellar GBR that slowly pulls the Moon toward the Earth is approximately:
,
,
,
,
9
,
which is 13 orders of magnitude smaller than the Newtonian gravitational field of Earth pulling on the Moon ~2.70 mm/s2. Here,
is the relativistic mass of the gravitational radiation energy contained within a spherical volume centered on Earth with a radius equal to the distance between Earth and Moon. This outcome confirms our earlier claim that the gravitational field generated by GBR is indeed extremely small, except in the case of large astrophysical structures, such as galaxies and clusters of galaxies.
At the edge of the Solar System, a distance of 143.7 billion kilometers10 from the Sun, where the gravitational force of our Sun fades, the additional increase in the Sun’s gravitational acceleration due to local interstellar GBR is approximate:
,
,
,
11
,
which is comparable in magnitude to the anomalous acceleration 8.74 × 10−10 m/s2 towards the Sun experienced by the Pioneer spacecraft [12] (launched in 1972 and 1973) as they moved beyond the orbit of Uranus (approximately 2.8 billion km from the Sun) on their way out of the Solar System.
NOTES
1The notion of light quanta was first conceived by Einstein in a paper where he proposed an explanation for the photoelectric effect in 1905.
2In accordance with relativity theory which has sufficiently established the equivalence of mass and energy, we shall refer to mass as energy in this study.
3For ease of evaluation, we shall not restrict generality by assuming that the energy distribution of the systems under consideration are approximately uniform (homogeneous and isotropic).
4This mysterious phenomenon is part of the more general dark matter problem [7], which in principle can be achieved in the framework of extended gravity [8].
5The plotted curves were generated from galaxy rotation curve data obtained from Refs. [5] [6] and the computed galaxy properties listed in Table 1.
6Computed values of the A for several spiral galaxies are provided in Table 1.
7The plotted curve and gravitational temperature of the Milky Way were derived from galaxy rotation curve data obtained from Ref. [5] and the computed galaxy properties listed in Table 1.
8Estimated energy density is computed with rotation curve data for the Milky Way in Ref. [5].
9The speed of light in vacuum.
10This value is based upon Sedna the most distant observable object known in our Solar System.
11The mass of the Sun.