[9] **viXra:0908.0103 [pdf]**
*submitted on 27 Aug 2009*

**Authors:** Carlos Castro

**Comments:** 8 pages, This article appeared in Adv. Studies in Theor. Phys. 1, no. 12 (2007) 603-610.

It is shown how one can attain the desired locally causal property of
QM in Clifford-spaces despite the spacelike separation of two massive
spin-½ particles involved in the Einstein-Podolksy-Rosen (EPR) experiment.
This is achieved by proving why the addition laws of the particles
poly-vector-valued momentum in Clifford-space is null-like. This is the
key reason why it is possible to implement a locally causal QM theory
in Clifford-spaces despite that QM has a non-local character in ordinary
spacetime. The two particles can exchange signals in Clifford-space encoding
their respective spin measurement values. Consequently, there
is no EPR paradox in the Clifford space associated with the Clifford
algebra Cl(3,1) of the underlying 4D spacetime.

**Category:** Quantum Physics

[8] **viXra:0908.0097 [pdf]**
*submitted on 26 Aug 2009*

**Authors:** John L. Haller Jr.

**Comments:** 24 pages

Advances in science are brought fourth by hypothesizing that the action of a system is a direct measure of the amount of information in that system. We begin to interpret this governing hypothesis by examining its implications to current research. From this investigation, we find four primary conclusions.

- To properly and completely quantify the amount of information contained within a particle (or system), one must add the self-information of both the wavefunction and its Fourier transform pair.
- Information in nature is found in packets quantized to an integer number of the natural units.
- Over a period of time, the energy of a system acts like an information rate and thus the information needed to describe that system for that period of time is equal to the product of the energy and the time divided by the minimum uncertainty.
- At a given instant in time, the angular momentum, J, of a system is in direct proportion to the amount of information that is contained within or can be transmitted by that system.

[7] **viXra:0908.0096 [pdf]**
*submitted on 26 Aug 2009*

**Authors:** Vladislav Konovalov

**Comments:** 11 pages

In the article a critic of the main notions of a modern physics is given

**Category:** Quantum Physics

[6] **viXra:0908.0075 [pdf]**
*submitted on 20 Aug 2009*

**Authors:** Dieter Gernert

**Comments:** 6 pages. Journal reference: Frontier Perspectives, vol. 14, no. 2, 8-13 (2005)

Whereas entanglement and nonlocality belong to the fundamental findings of quantum theory,
possible extensions to macroscopic systems outside the quantum laboratory are scarcely
studied. This paper analyses conditions for entanglement to occur on a macrophysical level.
An empirical basis is given by historic episodes and modern quantitative data. Theoretical
understanding can start from the concept of perspective notions; the crucial new term is
"*common prearranged context*", which characterizes the preparation to be made in advance
(or naturally given conditions) in order to enable entanglement. A mathematical formalization
is possible and gives some insight about how to handle perspective notions.

**Category:** Quantum Physics

[5] **viXra:0908.0062 [pdf]**
*submitted on 10 Aug 2009*

**Authors:** Hamid V. Ansari

**Comments:** Pages.

As we know probability of finding a system in one of its accessible
states is proportial to the Boltzmann factor. It is shown that contrary to
what is thought at present in this proportion the energy appearing in the
Boltzmann factor is not a variable but it is a constant and the variable is
the state accessible for the system having this constant energy. So, what
at present is accepted as Boltzmann factor is not real. Deduction of the
Maxwell velocity distribution as an instance of the consequences of the
real Boltzmann factor, and the first deduction of the relation E = hν
as an instance of the consequences of the wrong Boltzmann factor are
presented. A logical review of some of the fundamental elements of the
statistical mechanics, that also contains some new viewpoints, has been
necessary. A factor is introduced in a general expression for molar specific
heat which plays the role of partition (not equipartition) of energy and
giving suitable amounts to it all the practical cases including ones related
to ideal gases and crystalline solids are coveredν

**Category:** Quantum Physics

[4] **viXra:0908.0061 [pdf]**
*submitted on 10 Aug 2009*

**Authors:** Hamid V. Ansari

**Comments:** Pages.

It is shown that contrary to what is thought the classical physics does
not predict a uniform distribution for the magnetic dipoles (silver atoms)
in a nonuniform magnetic field in the Stern-Gerlach experiment. Its prediction
for a concentrated beam is obtained in the form of a circular surface
such that the density of the dipoles is much more near the edge than near
the center. Some experiments are proposed for testing the contents of the
article.

**Category:** Quantum Physics

[3] **viXra:0908.0060 [pdf]**
*replaced on 2013-07-04 10:43:36*

**Authors:** Hamid V. Ansari

**Comments:** Pages.

An electromagnetic wave with the wavelength lambda, which has some
energy, descends on an electron and makes it move in the same direction
of propagation of the wave. The wave makes the moving electron
oscillate with a lower frequency. A simple analysis shows that this
moving oscillating electron radiates, in the direction making angle theta
with the direction of the incident wave, an electromagnetic wave which
its wavelength is bigger by a factor proportional to lambda(1 − cos theta).
The mechanism presented for pushing the electron, necessitates that Camton scattering to cease if the experiment is performed in vacuum. (I'm ready to prepare for doing such a critical test experiment in any university as a guest researcher.)

**Category:** Quantum Physics

[2] **viXra:0908.0034 [pdf]**
*submitted on 8 Aug 2009*

**Authors:** Vladislav Konovalov

**Comments:** 15 pages

In the article the different aspects of interplay of fields with field carriers are reviewed.

**Category:** Quantum Physics

[1] **viXra:0908.0007 [pdf]**
*replaced on 6 Aug 2009*

**Authors:** Rati Ram Sharma

**Comments:** 12 pages

Heisenberg argued that wave and particle are too exclusively different in
properties, making the intrinsic wave-quantum unity of light impossible to visualize and
describe by the language. He invented mathematical Quantum Theory to circumvent
visualization and inadequacy of language. But mathematics too is a language to supplement
description. He used it to superimpose hidden concepts leading to the Uncertainty Principle.
In Unified Theory the wave & particle aspects of electromagnetic radiation and moving
material particle coexist blended together as wave-quantum UNITY. This is also supported
by experiments. The wave-or-quantum DUALITIES of Quantum Theory appear due to
experimental limitations to observe only one and not both of the two aspects simultaneously.
Conservation of mass & momentum are inviolable. Matter's creation from, or dissolution
into, 'nothing' is unrealistic. So the Heisenberg's Uncertainty Principle is rejected as
unrealistic and new Principle of Null Action with universal applications is introduced. The
Copenhagen interpretation of Quantum Theory is reappraised critically.

**Category:** Quantum Physics