[7] **viXra:0702.0059 [pdf]**
*submitted on 25 Feb 2007*

**Authors:** Thomas R. Love

**Comments:** recovered from sciprint.org

In the standard model, isospin is not defined for all elementary
particles nor is it conserved in all interactions. A study of the isospin
subalgebra in the author’s U(3, 2) theory of matter shows that the
standard model assigned the wrong isospin values to many elementary
particles. The redefined isospin is defined for all particles and is
conserved in all interactions. This leads to a new interpretation of the
isospin algebra as a model of pion exchange between protons in the
nucleus.

**Category:** High Energy Particle Physics

[6] **viXra:0702.0053 [pdf]**
*submitted on 25 Feb 2007*

**Authors:** Thomas R. Love

**Comments:** recovered from sciprint.org

Using the spinor differential operator representation of U(3, 2) to
explore the hidden symmetries of the complex space-time U(3, 2)/U(3, 1)x
U(1) leads to an interpretation of this complex space-time as excited
states of Anti-de Sitter space-time. This in turn leads to new Lie Algebraic
Quantum Field Theory and a mathematical model of the internal
structure of elementary particles as oscillations of complex space-time.
This is a quantum theory of gravity which satisfies Einstein’s criteria
for a unified field theory

**Category:** High Energy Particle Physics

[5] **viXra:0702.0052 [pdf]**
*submitted on 25 Feb 2007*

**Authors:** Carl A. Brannen

**Comments:** recovered from sciprint.org

Since 1982 the Koide mass relation has provided an amazingly accurate relation between the
masses of the charged leptons. In this note we show how the Koide relation can be expanded to
cover the neutrinos, and we use the relation to predict neutrino masses.

**Category:** High Energy Particle Physics

[4] **viXra:0702.0051 [pdf]**
*submitted on 25 Feb 2007*

**Authors:** Marco A. Pereira

**Comments:** recovered from sciprint.org

This paper presents a simple and purely geometrical Grand Unification Theory. Quantum Gravity,
Electrostatic and Magnetic interactions are shown in a unified framework. Biot-Savart Law is
derived from first principles. Unification symmetry is defined for all the existing forces. A 4D
Shock-Wave Hyperspherical topology is proposed for the Universe together with a Quantum
Lagrangian Principle resulting in a quantized stepwise expansion for the whole Universe along a
radial direction in a 4D spatial manifold. The hypergeometrical standard model for matter is
presented.

**Category:** High Energy Particle Physics

[3] **viXra:0702.0050 [pdf]**
*submitted on 25 Feb 2007*

**Authors:** Hu Changwei

**Comments:** recovered from sciprint.org

The neutrinos and electric charge are the two essences that are formed
the particles: Neutrino added to integral charge making up the lepton with electric
charge; neutrino added to fractional charge making up the quark. The ether is
composed by particles, it is the assembly of the bosons of the least energy state. The
transformation among the particles is the course that transferred electric charge and combined
anew among the particles, and together with virtual particles generally. This description can
accord with actual facts, it is the show of the reasonableness. Some examples will be given by the
disintegration of the part of particles.

**Category:** High Energy Particle Physics

[2] **viXra:0702.0049 [pdf]**
*submitted on 25 Feb 2007*

**Authors:** Roger Ellman

**Comments:** recovered from sciprint.org

The rest mass of the neutron is exactly equal to the rest mass of a proton plus that of an electron plus the mass equivalent of the kinetic energy of those two particles after they have electrostatically accelerated from very far apart toward each other to a separation distance of a proton diameter. That fact is either a remarkable coincidence or evidence that the neutron is a combination of a proton and an electron. The calculation of this sheds new light on the nature and significance of the Lamb Shift.

**Category:** High Energy Particle Physics

[1] **viXra:0702.0048 [pdf]**
*submitted on 25 Feb 2007*

**Authors:** V. Christianto

**Comments:** recovered from sciprint.org

While the idea of unification of gravitation and
electromagnetic theories via Kaluza-Klein metric is known for decades,
there is known disadvantage that 5th dimension is not yet observed in
experiments. In the meantime, there are known experiments suggesting
analogy between condensed matter physics and various cosmological
phenomena, therefore it seems reasonable to expect to observe this 5th
dimension via condensed matter physics. However, only few attempts have
been made in this direction. In the present article we argue that it is possible
to find neat linkage between Kaluza-Klein metric and condensed matter
physics via spinning string metric and Aharonov effect. From this
viewpoint, elementary particles could be described from excitation of
quantized spacetime. We start with alternative description of fine structure
of hydrogen in terms of four -velocity (vierbein). An obvious advantage of
the alternative interpretation of hydrogen fine structure and spin outlined
here is that it could be used to find direct observables, in particular using
superfluid experiments. This vierbein representation implies that elementary
particles could also be described in terms of phonon metric. Some
prediction of elementary particles is also discussed, in particular in the
context of Meessen’s framework. While for known particles our prediction
is essentially similar, for new prediction beyond Standard Model the present
article suggests that there is ‘shifting’ of time- component of the
modified-Minkowski metric due to Kaluza-Klein effect. Further observation to verify
or refute this proposition is recommended. Other viable observation method
is also considered, using Cherenkov radiation. In effect, this proposition of
describing elementary particles from excitation of phonon metric seems to
support the known condensed- matter analogue of chromodynamics theory
with gluonic interaction, albeit from different viewpoint.

**Category:** High Energy Particle Physics