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What is the Higgs Boson, and why is it so
important?
The Higgs boson is, if nothing else, the most
expensive particle of all time. It's a bit of an
unfair comparison; discovering the electron, for
instance, required little more than a vacuum
tube and some genuine genius, while finding the
Higgs boson required the creation of
experimental energies rarely seen before on
planet Earth.
Read More.
On 4 July 2012,
the ATLAS and CMS experiments
at CERN's Large
Hadron Collider announced
they had each observed a new particle in the
mass region around 126 GeV. This particle is consistent
with the Higgs boson predicted
by the Standard Model. The Higgs boson, as
proposed within the Standard
Model,
is the simplest manifestation of the Brout-Englert-Higgs
mechanism.
Other types of Higgs bosons are predicted by
other theories that go beyond the Standard
Model.
Read More.
Light charged Higgs boson
Nowdays,
number of articles have published that are
discussed on the light charged Higgs boson.
In
light of the recent discovery of a neutral Higgs
boson,
H
obs
with a mass near 125 GeV,
we reassess
the LHC
discovery potential of a charged Higgs boson, H+,
H-
,
in the W+,
W-
Hobs decay
channel.
Read More.
Also,
there is an interesting discussion with title: "Light
charged Higgs boson scenario in 3-Higgs doublet
models" about light
charged Higgs bosons
that has published in 2016.
Read More.
A new mechanism of Higgs bosons
in producing charge particles
While
developing quantum chromo-dynamics, some new
points of view of Higgs bosons have been
introduced and also have been put into
discussion about the other types and some
specifications of Higgs bosons. In the published
articles in the recent years, most attractions
have been noticed toward Higgs charges. Most of
them have been paid attention to the Higgs
bosons and electro-weak bosons but no any more
relations between gravity and Higgs has been
said or noticed, yet. (See article's
references).
In this article, according to
gravitational
blue-shift it has been tried to investigate the
Mossbauer effect and
Pound-Rebka experiments and
their interaction between gravity and photon
from point of view Higgs field. Blue-shift and
Mossbauer effect indicates clearly that three
different Higgs bosons cause increasing photon
mass while they have the electromagnetic
specifications. These Higgs bosons are called
positive and negative color-charges and
color-magnet
which
has explained very
precisely.
Iincreasing intensity of electrical field and
magnetic field during photon falls in
gravitational field due to increasing of photon
energy
According to above figure,
when a photon is falling in the gravitational
field, in interaction
between the photon and gravitons, here suppose
three identified gravitons; one graviton
behaves like positive electrical charge
H+ while another graviton
behaves like negative
electrical charge H-
which these two gravitons annihilate
their electrical charges. The
third graviton behaves like magnetic
field Hm ,
then two vertical electrical and magnetic
fields increase gradually and they become
stronger and stronger.
These are three different
kind aspects of Higgs bosons which enter
into structure of photon. This assumption is
acceptable because when photon is falling
in gravitational field, both its electrical
field and magnetic
field increase. But photon is neutral of
electrical charge. So, there are two
groups of particles which behave like
charges and they make electrical field. These
two groups annihilate
the electrical effect of the others.
Read More.
Contains: names, biographies and lectures
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