Dark energy

Dark energy is one of two concepts (the other is dark matter) that Big Bang cosmologists and astrophysicists have invented to explain the most serious differences to date between astronomical observations of an expanding universe and their own expectations. It is "the most popular way to explain recent observations that the universe appears to be expanding at an accelerating rate"; Astronomers and cosmologists have been speculating on the nature of this dark energy for ten years.

The problem
In 1998, the Supernova Cosmology Project observed 42 Type Ia supernovae, most of these from the ground, in an effort to measure the rate of deceleration of the expansion of the universe. (Type Ia supernovae are objects of easily discernible brightness and thus are favorite objects for standardization of redshift and hence of the speed of expansion.) These supernovae were actually much dimmer than expected, a finding that indicated an acceleration of expansion, not the deceleration that gravitational attraction would produce. A competing group, the High-Z Supernova Search Team, reported similar results from their observations of 14 other supernovae. (The symbol z stands for redshift in this context.) The findings of an accelerated universe came as a profound surprise to all interested observers and commentators. More recent surveys have shown that the discrepancy persists.

In conclusion dark energy is not been observed nor reproduced in a lab.

The solution from creation science
John Hartnett, in Starlight, Time and the New Physics, reminds his readers that Moshe Carmeli first formed a new model, called cosmological relativity, and through this model predicted that the universe would in fact appear to be accelerating. He made this prediction in 1996, two years before the publication of the Type Ia supernova data and the introduction of the idea of "dark energy" into cosmological discussions. In making this prediction, Carmeli did not invoke either dark energy or dark matter.

Hartnett extended Carmeli's model and discarded several assumptions that Carmeli initially had thought were safe. This included the assumption that the matter density of the universe is at the critical level for a "coasting" universe.

The full derivation of Hartnett's field equation that describes the motion of far-off objects is included in Appendix 2 of his book. Briefly, Hartnett begins with Moshe Carmeli's relativity model, which adds a dimension of the radial velocity of a far-off object to the Einsteinian dimensions of space and time. This radial velocity is related to the distance of the object by this equation:

$$v = \bigg( \frac{1}{\tau} \bigg) r$$

where $$\tau$$ is a constant (evaluated at 4.28 * 1017 s) that is the reciprocal of the Hubble factor H0 in weak gravity.

Adding this dimension requires adding a new term to the classic space-time interval, and so:

$$ds^2 = \Bigg( 1 + \frac{\Phi}{c^2}\Bigg)c^2dt^2 - dr^2 + \Bigg(1 + \frac{\Psi}{\tau^2}\Bigg) \tau^2 dv^2$$

where r is the distance of the object from earth (or more properly, our galaxy).

An observation of a far-off object is typically made at a given moment and from a given place, and so ds=dt=0. So the above equation simplifies to:

$$ - dr^2 + \Bigg(1 + \frac{\Psi}{\tau^2}\Bigg) \tau^2 dv^2 = 0$$

Carmeli's solution is:

$$\frac{dr}{dv} = \tau \sqrt{1 + (1 - \Omega ) \frac{r^2}{c^2\tau^2}}$$

where $$\Omega$$ is the mass-energy density fraction of the universe. Specifically, $$\Omega = \rho/\rho_c$$, where $$\rho_c$$ is the critical mass density, above which the universe would be closed and destined to collapse.

The integral of the above equation, expressed in dimensionless numbers, is:

$$\frac{r}{c\tau} = \frac{\sinh(\beta \sqrt{1-\Omega})}{\sqrt{1-\Omega}}$$

where $$\beta$$ = $$v/c$$ is the radial velocity of the object, as a fraction of the speed of light. This fraction is itself a function of the redshift of the object (symbol: z):

$$\beta = \frac{(1+z)^2 + 1}{(1+z)^2 - 1}$$

The key fact is that the matter density anywhere in the universe is also a function of redshift. In the simple case of "flat" space,

$$\,\Omega = \Omega_m(1+z)^3$$

where $$\Omega_m$$ is the weighted-average mass-energy density of the universe in the present epoch.

Hartnett tested these equations against the High-Z Supernova Search Team data. To do this, he used these equations to convert $$r/c\tau$$ to an absolute magnitude:

$$\,m(z) = M + 5 \log D_L (z;\Omega)$$

Here,

$$D_L (z;\Omega) = \frac{(1+z)}{\sqrt{1-\beta^2}}\frac{r}{c\tau}$$

is an independent luminosity distance, and

$$M = 5 \log \bigg(\frac{c\tau}{Mpc}\bigg) + 25 + M_B + a$$

where $$M_B$$ is the highest absolute magnitude of any given supernova and $$c\tau$$ is expressed in megaparsecs.

Recall that $$\beta$$ is a function of z, and r is sensitive to the mass-energy density fraction.

Hartnett plotted the difference $$M-M_B$$ against redshift for the supernovas studied most recently by Riess and Astier. He then adjusted the parameters $$a$$ and $$\Omega_m$$ to achieve the best statistical fit to the observations. He obtained these values:

$$\,a = 0.2284$$

and

$$\,\Omega_m = 0.0401$$

The second value is consistent with a mass-energy density that is four percent of critical. This is about twice as much matter as Fukugita et al. have determined that the universe has within it, but also at the upper limit of the range of that value. It is also the same as the fraction of mass-energy in the universe that most evolutionists now believe to be composed of ordinary or baryonic matter (see below).

Hartnett's model thus predicts as much mass-energy as other astronomers have already estimated that the universe has, and no more, within the limits of that estimate.

The dark energy concept
Reiss, Astier, and their respective teams did not use this model. Instead, they relied upon the Friedmann-Lemaître cosmological model. That model predicted far more mass-energy than the universe possesses, beyond any rational estimate.

Saul Perlmutter, Michael Turner, and Martin White appear to have coined the term dark energy to name the phenomenon that is causing the apparent acceleration that they found. The term appears again in the more comprehensive paper of Bahcall, Ostriker, Perlmutter, and Steinhardt, that proposes that a heretofore unsuspected form of energy "overcomes the gravitational self-attraction of matter and causes the expansion [of the universe] to speed up."

In 2001, Reiss and his colleagues used the Hubble Space Telescope to capture on film the furthest supernova then seen, SN1997ff, at a distance of 10 billion light-years. The magnitude and redshift of this object were consistent with a decelerating expansion. This is consistent with the model that Reiss and others were forming at the time, stating that the expansion of the universe was initially decelerating and later accelerated after its matter density dropped below a critical level.

In 2003, a survey of 11 Type Ia supernovae by the HST confirmed the earlier findings of an accelerated expansion of the universe. Astronomers consider this the most definitive evidence to date for the existence of dark energy.

Nature of dark energy
Dark energy today is inferred, not detected. The calculated quantity of dark energy is the apparent excess of energy that somehow abruptly accelerated the expansion of the universe. Current estimates of the time that has passed since this acceleration occurred vary from 5 to 7.5 billion years.

naturalistic cosmologists estimate that 70 percent of the total energy in the universe consists of dark energy. Dark matter occupies another 25 percent. The remaining portion is the familiar, or baryonic matter of which all objects are made.

Uniformitarian cosmologists have three theories of what form this energy might take:
 * 1) It is a fundamental property of the universe, as Albert Einstein originally suggested. Einstein's original idea was that this force, which he called a "cosmological constant," would exactly counterbalance gravity and thus keep all galaxies and other objects of similar size in the same place. Einstein initially discarded his own findings after Edwin Hubble showed that the universe was expanding. Some modern cosmologists suggest that Einstein might have been right after all.
 * 2) It is a previously unknown type of energy fluid or field, and perhaps even a fifth elemental force, in addition to the previously known four forces of gravity, the electromagnetic force, and the weak and strong nuclear forces. Some scientists name this new force "quintessence" (literally, fifth essence), a term that ancient Greek philosophers once coined for a fifth "element" of nature in addition to the four elements that they thought they knew (fire, air, earth, and water).
 * 3) It is not a new property or force but a manifestation of an error of our understanding of an old one, namely gravity.

Implications of dark energy
Evolutionistic cosmologists have thus far realized only that their understanding of cosmology is incomplete. They now know that the universe is expanding, that this expansion is accelerating, and that their existing models cannot account for this acceleration or begin to suggest a cause. They believe also that dark energy can explain the current temperature of the Cosmic Microwave Background radiation. But they are no closer to defining the nature of dark energy than they were when Perlmutter et al. first coined the term.

This has not stopped them from speculating on what might happen to the universe in the future. They currently recognize three possibilities:
 * 1) The universe will expand indefinitely and isolate our galaxy.
 * 2) The "quintessential" substance will reverse its repulsive effect and become attractive. This will stop the expansion and contract the universe into a point, an event they call the "Big Crunch."
 * 3) The universe will expand rapidly enough to tear the fabric of space and ultimately cause all baryonic matter to disintegrate, an event they call the "Big Rip."

Other scientists raise the question of whether the proportion of dark energy in the universe is a fundamental quantity of space. If it is not, they say, then this universe is only one of many.

Creationist criticism
Dr. Walt Brown wrote the following about the concept of dark energy: Neither “dark matter” (created to hold the universe together) nor “dark energy” (created to push the universe apart) has been seen or measured. We are told that “most of the universe is composed of invisible dark matter and dark energy.” Few realize that both mystical concepts were devised to preserve the big bang theory.

Dark energy is a mathematical convenience. Some authorities admit that it may never be detectable. One reason why no one would ever detect it is that it represents an error. Evolutionistic cosmologists have admitted that dark energy might represent an error of their understanding of gravity. Creationists suggest that the error is far more fundamental.

Secular criticism
David Cline wrote in Scientific American in 2003 the following: We know little about that sea. The terms we use to describe its components, dark matter and dark energy, serve mainly as expressions of our ignorance. Similarly, David Shiga authored an article in 2007 published by New Scientist titled "Is Dark Energy an Illusion?".

A Competing Secular Explanation
Timothy Clifton, at Oxford University, said in an interview published at Space.com on October 1, 2008 that the solar system might be enclosed in a volume of space having a disproportionate lack of matter. According to his "void model," light from far-distant objects appears dim, not because the objects are retreating from the earth or even because the cosmos is expanding, but because the void condition does not focus the light as a matter-filled cosmos normally would. Clifton expresses one misgiving about his model that clearly reveals his worldview, however: it would negate the so-called Copernican Principle and require astronomers and cosmologists to regard the earth as a special place.

Proposed investigations
Fermilab's Experimental Astrophysics Group has proposed a Dark Energy Survey, using a special 500-megapixel camera mounted on a ground-based telescope.

NASA and the United States Department of Energy have also proposed a Joint Dark Energy Mission, essentially a new, very-high-resolution space telescope. Three different telescope designs are now under study. Timothy Clifton, the proponent of the "void model" mentioned above, hopes that observations by JDEM might provide a reliable test of his model.