The Vacuum Catastrophe - Zero-Point Energy
Date: Sunday, February 01, 2015 @ 21:30:24 EST
Topic: Science

Video published by : The Vacuum Catastrophe - Zero-Point Energy

Here is more science based background on the amount of energy in the vacuum (Jordan Maclay/Quantum Fields LLC):

"...If you have a hot body in equilibrium with its surroundings, it is radiating and reabsorbing photons (quantized bundles of electromagnetic radiation) of all wavelengths. The energy of a photon of frequency f is Planck's constant h times the frequency hf . The energy distribution of these photons is given by the Planck blackbody equation. If you imagine cooling the body and surroundings to absolute zero, you would find that a temperature independent electromagnetic field remained. This electromagnetic field, which is always present even if no matter or charged particles are present and the temperature is absolute zero, represents the lowest state of the electromagnetic field. The corresponding fluctuating electromagnetic field is called the zero-point (ZP) field of the electromagnetic field. The presence of this zero-point field is predicted by QED (Quantum Electrodynamics).

QED is the most precise physical theory we have; its predictions have been verified to 1 part in 10 billion! The zero-point field is the "ground state" of the electromagnetic field. In this ground state, the equations indicate that no ordinary physical photons are present, yet electromagnetic energy is present. The energy for a given frequency is ½ hf , one half of the usual energy of a photon. Sometimes the zero-point field is described as consisting of "virtual" or very short-lived photons, that appear and disappear before it is possible to detect them. The presence of zero-point fluctuations has been verified experimentally with very accurate measurements of the Lamb Shift, other atomic energy level shifts, the magnetic moment of the electron, and the Casimir force. QED predicts that the number of ZP quanta (½ hf ) of frequency f is proportional to the square of the frequency. This gives an energy density for the vacuum that goes as the cube of the frequency.

Special relativity requires that any observer going through space cannot tell how fast she is going in an absolute sense. Thus the zero-point fluctuations must look the same, independent of her velocity as she travels through space. Therefore the Doppler shifted frequency spectrum must look the same as the unshifted frequency spectrum. This requirement of special relativity results in an energy density of the zero-point fluctuations identical to that predicted by QED, namely an energy density proportional to the cube of the frequency. Summing over all the frequencies present, gives a total energy density in the vacuum of which is proportional to 1/L4 where L is the shortest wavelength of the ZP fluctuations allowed. If we take L as zero, then we obtain an infinite energy. Applying quantum principles to general relativity (geometrodynamics) suggests that at lengths shorter than the Planck length (10**-35 m), the nature of space-time fluctuates, and therefore no meaning can be ascribed to a length shorter than the Planck length. Thus we could use the Planck length as a cutoff.

The energy density of the ZP fluctuations in empty space (according to QED) is about 10**114 joules/cubic meter if we use the Planck length (10**-35 m) as a cut-off.

General Relativity and Vacuum Energy
In general relativity, any form of energy has an equivalent mass, given by E = mc**2, and is therefore coupled to gravity. This enormous zero-point energy density is equivalent to a mass density of about 10**92 kg/cc, and would be expected to cause an enormous gravitational field. This large field leads to some major problems with general relativity, such as the collapse of the universe into a region of space that is about 1 Planck length across. Thus we have an inconsistency in two very important and well-verified theories, QED and General Relativity. A brief discussion of this problem is given in the excellent book "Lorentzian Wormholes" (Springer-Verlag, 1996, p. 82) by Matt Visser.

As a brief aside, it is amusing to compute the equivalent mass for a region of the vacuum about the size of a proton, which is approximately a sphere about 10**-13 cm across, using the enormous energy density formally predicted above. This process yields an equivalent mass of about 10**53 kg. This means the vacuum energy contained within a region of space the size of a proton is equivalent to a mass of about 10**53 kg. A very rough estimate of the number of nucleons in the universe is 10**80. This number is based on the statistical distribution of stars in galaxies and the number of galaxies. Most of the mass of matter is in nucleons, so the mass of the universe is roughly the weight of a proton times 10**80 or about 10**53 kg, which is the same as the mass equivalent of the vacuum energy in a region the size of a proton. Conclusion: A volume the size of a proton in empty space contains about the same amount of vacuum energy as all the matter in the entire universe!!!!!

This simple-minded computation is interesting when we think about the big bang theories, in which ultra dense matter in a small region of space explodes and develops into all the matter in the known universe. Could it be possible that the vacuum energy in a small region or space underwent a transformation into mass? This simple-minded computation does not include other forms of energy, such as black holes, or gravitational potential energy.

As mentioned above, the enormous density of the vacuum energy appears to cause severe conceptual problems in general relativity since the energy couples with gravity. We can reduce the zero-point energy by the use of a larger cutoff wavelength. One choice for the short wavelength limit is the Compton wavelength of the proton as suggested by Nobel Laureate physicist Richard Feynman. The energy density is then reduced to about 10**35 joules/cubic-meter corresponding to an equivalent mass density of 10**12 kg/cc. To appreciate the enormity of this number, compare it to the chemical energy of a fuel, 10**15 joules/cubic meter, to the energy density of matter, 10**20 joules/cubic meter, and to the energy density of a nucleus, 10**30 joules/cubic meter.

This energy density is still very large, but does look better from the viewpoint of general relativity. However, now the bad news. The use of a cut-off is actually in conflict with special relativity, because the value of the cutoff will depend on the velocity of the rest frame of the observer. This would mean that the vacuum energy density would depend on your relative motion, which is a violation of special relativity. So again we have an inconsistency between well verified theories.

A variety of "solutions" have been proposed to resolve the inconsistencies between general relativity and quantum theory, including the use of a "renormalized" vacuum energy. In this approach, the vacuum energy of empty space is set equal to zero, and only changes in vacuum energy, such as those that occur in Casimir effects, are included in the formulation of general relativity. Other approaches include supersymmetry (SUSY) and the use of extra dimensions (Kaluza-Klein theory), and superstrings. Another approach might lie in a reinterpretation of Mach's principle. In the spirit of Mach’s principle the mass of an object is interpreted as the effective gravitational attraction of the object to all the rest of the matter or energy in the universe. Perhaps the vacuum energy needs to be included in this formulation. Many think that a new theory of quantum gravity is needed to resolve these conflicts.

At this time there is no consistent interpretation of the zero-point energy density in empty space. … It’s an embarrassment to physicists to have such a conflict between such well verified and accepted theories. In fact it is so painful, that most physicists don’t even want to think about it…"

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