In light of of Naturalist arguments, are predicated: that QM particles prove something can pop up out of nothing with no cause. Quantum theory seems to confirm the notion that it is possible for the universe to begin with no cause. In terms of the TS argument that would mean that no organizing principle is necessary to explain order.
The second contender for a theory of initial conditions is quantum cosmology, the application of quantum theory to the entire Universe. At first this sounds absurd because typically large systems (such as the Universe) obey classical, not quantum, laws. Einstein's theory of general relativity is a classical theory that accurately describes the evolution of the Universe from the first fraction of a second of its existence to now. However it is known that general relativity is inconsistent with the principles of quantum theory and is therefore not an appropriate description of physical processes that occur at very small length scales or over very short times. To describe such processes one requires a theory of quantum gravity. [1]
This statement is more admission than documentation. It admits that quantum theory might not pertain to the universe as a whole. After all the theory has only been validated under normal conditions of space/time, temperature and the like. We have no idea if it still applies at the big bang expansion where the laws of physics seem to be suspended, temperature and time approach infinity. “What we do know is that massive objects do not exhibit quantum behavior. No one can be sure that a new-born universe would obey quantum theory as we know it..”[2]Moreover the statement admits that the theory requires a theory of quantum gravity in order to apply as a theory of origins. Do we have a theory of quantum gravity that has been validated empirically?
Lawrence Krauss in his book, A Universe from Nothing, [3] argues that quantum theory means that the universe came from nothing based upon the assumption that quantum particles do the same. Krauss argues that the eternal laws of Quantum mechanics produce particles out of nothing when the instability of vacuum states causes quantum fields to shift and produce different kinds of particles. [4] This seems like scientific proof but all it really says is that nothing became unstable and turned into something, no thought as to how that could be. There's a deeper trick, however, in that the terms don't really mean what they seem to mean. David Albert (a Philosopher with Ph.D. in physics) exposed the meaning of terms and exploded the whole project.
Albert first points out that tracing the universe back to some physical property or cause is not an explanation as to why there is something rather than nothing.
What if he were in a position to announce, for instance, that the truth of the quantum-mechanical laws can be traced back to the fact that the world has some other, deeper property X? Wouldn’t we still be in a position to ask why X rather than Y? And is there a last such question? Is there some point at which the possibility of asking any further such questions somehow definitively comes to an end? How would that work? What would that be like?[5]
Secondly, he points out that going back to the enlightenment, science has always assumed that at the “bottom of everything” there is “some basic, elementary, eternally persisting, concrete, physical stuff.” [6] Newton had it that this “stuff” consisted of particles. At the end of the nineteenth century it was particles and electro-magnetic fields. Albert argues that since that time all of physics is basically about “how that elementary stuff is arranged.”[7] The laws don’t tell us where the elementary “stuff” came from, not even laws of quantum mechanics. The laws do not tell us where the fields came from, let alone where the “laws” themselves came from. Moreover, contrary to all previous theories, quantum theory particles are understood as arrangements of fields. Some arrangements correspond to certain numbers and kinds of particles, some correspond to no particles.[8] This latter arrangement, Albert tells us, is what they call “vacuum states.” According to Albert, Krauss is arguing that the laws of relativistic quantum field theories “entail that vacuum states are unstable. And that, in a nutshell, is the account he proposes of why there should be something rather than nothing.”[9]
There is no explanation here. No hint as to how nothing could become something. If nothing comes out of some prior condition we don't know. Krauss is just assuming something from nothing. That's important because prior conditions have to be accounted for. There are problems with this account. First, we have just seen, it assumes laws and fields with no explanation as to where othey came from. Secondly, when physicists say “nothing,” they don’t mean real actual nothing, absence of anything, they really mean vacuum flux; that is the pre existing framework of law and field and the arrangement of these things and the sporadic popping in-and-out of prior existing particles. As Albert says, “Relativistic-quantum-field-theoretical vacuum states — no less than giraffes or refrigerators or solar systems — are particular arrangements of elementary physical stuff..” [10] “Nothing” in terms of no particles does not mean “nothing” in terms of no fields, or no laws. Thus “nothing” doesn’t mean “nothing,” it means something for which we still must account.
The particles doing the popping are “virtual particles,” meaning they are made up of combinations of other particles that come together for a short time then break apart again. “Virtual particles are indeed real particles. Quantum theory predicts that every particle spends some time as a combination of other particles in all possible ways. These predictions are very well understood and tested.”[11]
Quantum mechanics allows, and indeed requires, temporary violations of conservation of energy, so one particle can become a pair of heavier particles (the so-called virtual particles), which quickly rejoin into the original particle as if they had never been there. If that were all that occurred we would still be confident that it was a real effect because it is an intrinsic part of quantum mechanics, which is extremely well tested, and is a complete and tightly woven theory--if any part of it were wrong the whole structure would collapse.
But while the virtual particles are briefly part of our world they can interact with other particles, and that leads to a number of tests of the quantum-mechanical predictions about virtual particles.[12]
Thus it's only said that they are coming from nothing because there's a new combination of particles that only exists for a short time. Yet they are actually coming from other particles. Quantum theory is not the best explanation for the age old question, why are we here where did it all come from? God not only provides an ultimate sources but is also a more elegant solution because one simple idea furnishes both the explanation of origins and also ties up morality and everything else into one neat solution.
see new apemdix to this article below imn fn [13]
Sources
1 CTC op. Cit.
2 Edgar Andres, “Review: the Grand Design,” Challies'.com, Tim Challies, on line reouce, URL:
http://www.challies.com/book-reviews/the-grand-design acessed 10/4/15
Andres is Emeritus professor University of London. Physicist and an expert on large molecules. Born 1932,
3 Lawrence M. Krauss, A Universe from Nothing: Why There is something Rather Than Nothing. New York, NY: Free press, a division of Simon and Schuster, 2012.
4 Ibid 189.
5 David Albert, “On the Origin of Everything ‘a Universe form Nothing’ by Lawrence Krauss,” New York Times Sunday Book Review (March 23, 2012). On line version URL: http://www.nytimes.com/2012/03/25/books ... rauss.html visited June 20, 2012. David Albert also has a Ph.D. in theoretical phsyics.
Albert is Frederick E. Woodbridge Professor of Philosophy at Columbia, and runs a MA program in philosophy and physics.
6 ibid.
7 ibid
8 ibid
9 ibid
10 ibid
11 Gordon Kane, “Are Virtual Particles Really Constantly Popping In and Out of existence? Or Are They Merely a Mathematical Bookkeeping Device For Quantum Mechanics?” Scientific American, (Oct. 9, 2006) on line version URL: https://www.scientificamerican.com/article/are-virtual-particles-rea/
american.com/article/are-virtual-particles-rea/ accessed 10/12/15
this article was moved this is the new URKL since first wrote my blog piece,
Kane is director of the Michigan center for theoretical physics at the University of Michigan at Ann Arbor.
12 Ibid.
this is the article
https://blogs.scientificamerican.com/observations/physicists-debate-the-many-varieties-of-nothingness/
here is a quote from scientificL American. Reporting om a debate (which included Krauss) on "what nothing Means."
speaking of empty space such as that between objects in a room or between nucleus of an atom and electrons:
This is what my essay was about virtual particles and how they are not popping out of nonexistence or lack of being but coming out of other particles that already exist,' this tells us two things:
(1) VP's are not coming from nothing but from pre existing particle which is called vacuum flx.
(2) Vacuum flux is QVS they are the same,so when you say no they are not coming from vacuum flux they are coming from QVS you are saying:these are not chick peas they are garbanzo beans.(garbanzo beans are chick peas)
this means noting is changed with my article it is right on target; when they talk about particles coming from nothing they really mean combining from pre existing particles that are in QVS. so where do those come from?
The article torches on this:
Quote
at that point one must interject metaphysics, there's nothing else to do.
Did you know that Krauss says he wants to eliminate philosophy because it has out lived it's usefulness? (Priesthood of knowledge)
Gordon Kane, director of the Michigan Center for Theoretical Physics at the University of Michigan at Ann Arbor, provides this answer.Virtual particles are indeed real particles. Quantum theory predicts that every particle spends some time as a combination of other particles in all possible ways. These predictions are very well understood and tested.Quantum mechanics allows, and indeed requires, temporary violations of conservation of energy, so one particle can become a pair of heavier particles (the so-called virtual particles), which quickly rejoin into the original particle as if they had never been there. If that were all that occurred we would still be confident that it was a real effect because it is an intrinsic part of quantum mechanics, which is extremely well tested, and is a complete and tightly woven theory--if any part of it were wrong the whole structure would collapse.But while the virtual particles are briefly part of our world they can interact with other particles, and that leads to a number of tests of the quantum-mechanical predictions about virtual particles. The first test was understood in the late 1940s. In a hydrogen atom an electron and a proton are bound together by photons (the quanta of the electromagnetic field). Every photon will spend some time as a virtual electron plus its antiparticle, the virtual positron, since this is allowed by quantum mechanics as described above. The hydrogen atom has two energy levels that coincidentally seem to have the same energy. But when the atom is in one of those levels it interacts differently with the virtual electron and positron than when it is in the other, so their energies are shifted a tiny bit because of those interactions. That shift was measured by Willis Lamb and the Lamb shift was born, for which a Nobel Prize was eventually awarded.Quarks are particles much like electrons, but different in that they also interact via the strong force. Two of the lighter quarks, the so-called "up" and "down" quarks, bind together to make up protons and neutrons. The "top" quark is the heaviest of the six types of quarks. In the early 1990s it had been predicted to exist but had not been directly seen in any experiment. At the LEP collider at the European particle physics laboratory CERN, millions of Z bosons--the particles that mediate neutral weak interactions--were produced and their mass was very accurately measured. The Standard Model of particle physics predicts the mass of the Z boson, but the measured value differed a little. This small difference could be explained in terms of the time the Z spent as a virtual top quark if such a top quark had a certain mass. When the top quark mass was directly measured a few years later at the Tevatron collider at Fermi National Accelerator Laboratory near Chicago, the value agreed with that obtained from the virtual particle analysis, providing a dramatic test of our understanding of virtual particles.Another very good test some readers may want to look up, which we do not have space to describe here, is the Casimir effect, where forces between metal plates in empty space are modified by the presence of virtual particles.Thus virtual particles are indeed real and have observable effects that physicists have devised ways of measuring. Their properties and consequences are well established and well understood consequences of quantum mechanics.[13] Michael Moyer, "Physicists debate the many verities of nothing." Scientific American, ( March 22, 2013) on lime versiom URL:
https://blogs.scientificamerican.com/observations/physicists-debate-the-many-varieties-of-nothingness/
here is a quote from scientificL American. Reporting om a debate (which included Krauss) on "what nothing Means."
speaking of empty space such as that between objects in a room or between nucleus of an atom and electrons:
This sort of nothing—the absence of matter—we might consider to be the first level of nothing, clarified J. Richard Gott, a physicist and cosmologist at Princeton University and the author of “Sizing Up the Universe: The Cosmos in Perspective.” It’s what scientists call a quantum vacuum state. It’s a box with everything taken out of it—all the stuff, all the air, all the light. “It even has a color—it’s black,” deadpanned Gott, who frequently demonstrated the best comedic timing of the bunch. Yet even in this nothing, something remains. Virtual quantum particles pop in and out of being, and the empty box still contains the basic scaffolding of existence: space, time and quantum fields." [end quote]
This is what my essay was about virtual particles and how they are not popping out of nonexistence or lack of being but coming out of other particles that already exist,' this tells us two things:
(1) VP's are not coming from nothing but from pre existing particle which is called vacuum flx.
(2) Vacuum flux is QVS they are the same,so when you say no they are not coming from vacuum flux they are coming from QVS you are saying:these are not chick peas they are garbanzo beans.(garbanzo beans are chick peas)
this means noting is changed with my article it is right on target; when they talk about particles coming from nothing they really mean combining from pre existing particles that are in QVS. so where do those come from?
The article torches on this:
Quote
But where did these come from? Was this something always there? We can trace the history of the universe back to the first instant after the Big Bang, when the cosmos was unimaginably hot and dense and expanding rapidly. But here the laws of physics break down, and with them our ability to reconstruct what came before—indeed, if its even proper to speak of a “before.” This space outside of the universe (though it is certainly misleading to call it a “space”) is the second kind of nothing—the complete lack of space and time and quantum fields. The absence not just of matter and energy, but of the conditions necessary for being."close Quote
at that point one must interject metaphysics, there's nothing else to do.
Did you know that Krauss says he wants to eliminate philosophy because it has out lived it's usefulness? (Priesthood of knowledge)
