"gravity beyond einstein"-series : gravitomagnetism - successes in explaining the cosmos
TRANSCRIPT
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GRAVITOMAGNETISMSUCCESSES IN EXPLAINING THE COSMOS
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The purpose of this presentation
- To explain what Gravitomagnetism exactly is and how the magnetic
part can be interpreted.
- To show that many cosmic issues can be explained by
calculating it strictly, without other assumptions, just by using
PART ONE
common sense.
- To show that the bending of light and the Mercury issue can be
purely deduced and dont need to be gauges for a theory.
- Explain my current research, consisting of a new theory of forces:
the Coriolis Gravity and Dynamics Theory.
PART TWO
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What is Gravitomagnetism?
Coulombs
ElectrostaticLaw
1 21 23C e
q q
F k r q Er= =
F F
NewtonsGravity Law
1 21 23N
m mF G r m gr
= =
q mke G
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Lorentz force ( )L2 2 1 2 1F q E v B= +
F F
v vq m
Equivalent
Lorentz force
for gravity ( )H2 2 1 2 1F m g v= +
B ?...
2
1m mN kg
s ss
= +
Oliver Heaviside
= gyrotation
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Heaviside Maxwell equations
( )H2 2 1 2 1F m g v +
4 G
Gravitomagnetic force =
gravity force + gyrotational force
The gravity field is radial (diverges) and its
amplitude is directly proportional to its mass
2 4c G j g t +
directly proportional to a mass flow
or an increasing gravity field and is
perpendicular to it (encircles it)
0 =
There are no gyrotational monopoles
g t The induced gravitation fields
amplitude is directly proportional to
an increasing gyrotation field andperpendicular to it (encircles it)(Minus sign inverses vector orientation)
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The meaning of Gyrotation A linear mass flux is encircled by a gyrotation field according
or
2 4c G j
2d 4l G m c
The local absolute velocity of the mass is
defined by an external gravity field
An external gravity field defines the zero velocity
22 G m R c =
In other words : the aether velocity of a mass is always zero
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Electromagnetism and Gravity
are totally similar
Maxwell equations and Lorentz forceare applicable to both
No further assumptions !
No further theories !
Just simple maths and common sense !
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A circular mass flow induces a dipole-like gyrotation
Ring SphereGyrotation
of a ring is
analogue
to themagnetic
field of an
electrical
The own gravity field defines the zero velocity
The local absolute velocity of the mass is defined by
the own gravity field
( )( )
ext 3 2 2
3
2
r rG Ir
r c r
=
dipole(steady
system)
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First effect of Gyrotation
sun
What happens to an inclined orbit of a planet ?
p sun p suna g v= + Lorentz- Heaviside
acceleration:
Every planets orbit swivels to the Suns equator plane.
Same occurs for : Saturn rings, disk galaxies.
Gyrotation transmits angular momentum at a distance by gravity.
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Examples: Swiveling to prograde orbits
Inclined retrograde orbit equatorial prograde orbit
retro rade
retrograde
re rogra eprogra e
prograde
sun
p sun p suna g v= +
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Stars velocity in disc galaxies
Consequence:
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Spherical galaxy with a spinning center
2 0sphere
G Mv = (Kepler)
Simplified explanation without dark matter
Consider nucleus with mass M0
and a mass
distribution with concentrical shells,
each with a massM0 :
Swiveled galaxy
2 0disc
0
G n Mv
k R= = constant
Milky Way : v= 235 km/s
The nucleus mass has totally changed :
m
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Spiral disc galaxies
Gyrotational pressure upon orbits
Swivelling of the orbits
side view
Swivelling time
Total life time
Further consequence:
High density of disc
Local grouping Local voids
top view
Winding time
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Second effect of Gyrotation
p pa g v= +
Lorentz-Heaviside acceleration :
Like-spinning planets with Sun
= unstable momentum
Opposite spinning planets
than Sun = stable momentum
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Third effect of Gyrotation
Gyrotational
Internal
gyrotation
Rotation
Gyrotation surface-compression forces
p pa g v= +
compressionforces
Centrifugal
force
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0 < surface compression < 3516
( )22x,tot 2 2
1 3 sin coscos 1
5
G m G ma R
R c R
=
2 23 cos sin sinG m G m
centrifugal gyrotation gravitation
35 16
F > Fc
y,tot 2 2a c R = +
gravitationgyrotation
y
x
Gyrotationalcompression forces
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R 21 5 CR Rr R
+
F
< Fc
For a fast spinning sphere (the equationis then almost spin-independent) :
Internal gyrotation and centripetal forces
for given values of
r
0
C
( )2
5CR G m c=
wherein
= critical compression radius
For large masses, small radii : ( )2
5 6 3 sinr R
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Supernovae examples
Caterinae SN 1987 - a
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hourglass
nebulahs-1999-32-a
More supernovae examples
hs-1997-38-a
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Prediction attempt : the shape of supernova stars
After the explosion of the sphere:
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Fourth effect of Gyrotation
Attraction and repelling between molecules
Ha g v= +
Horizontal reciprocity
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Like spins attractOpposite spins repel
Vertical reciprocity
Va g v= +
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Application: the expanding Earth
Natural preferential
ordering inside the
Earth:
- aligns with
- vertical attraction
- horizontal repel
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Stars life cycle
E
X
PA
N
C
O
LL
A
Sun
I
O
N
P
S
E
Red Giant
White
Dwarf
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Probable process to a white dwarf
The star expands and becomes a red giant
- Spin speed decreases dramatically
- Stars nuclear activity decreases dramatically
- Photosphere-matter gets continuously lost
Spin accelerates again
Collapse with matter release
Molecules spin vector becomes less oriented
Again compression
Expansion stops
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Other succesful applications
of Gyrotation
- The Mercury perihelion advance
22 21 12 2 2 3 2
cos cosm M m M m M R
F G G v G v
= + +
v2v1
With v1 the Suns velocity in the Milky Way, v2 Mercurys velocity and
is Mercurys angle to the Milky Ways centre.
Gravity Suns motion in Milky Way Suns rotation
(negligible)
2 226 v c =
2 21 224v v= (excentricity neglected)
( )2
2
av0
1cos
2
=
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- The bending of light grazing the Sun
v1
2 21, 2 2 2 2
2 cos cos2 5
m M Rm M m M F G G v G
r r c r c
= + +
With v1 the Suns velocity in the Milky Way, the angle between the
ray and the Suns orbit and the Suns latitude where the ray passes.
Gravity and
gyrotation
Suns rotationSuns motion in Milky Way
(neglectible)
O h li i
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The formation of a set of tiny rings about Saturn
Ring section
Other application:
Motion,
collisionsPressure
without
motionTurbulence,
separation
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- The fly-by anomaly
-Strongly onto the equator
The acceleration is :
25
45
tor
onto
poles
(0 is the equator)
-Weak onto the poles when
flying under inclination of 25
-Absent near 0 and near 45
Poles
onto
equ
( )2E E St, 2 23
sin cos 2 1 3 sin sin 4 cos42
G Ia
r c
=
E for Earth, S for satellite , is the satellites inclination to the Earths equator.
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Stars are vacillating in the halo of disc galaxies
- The halo of disc galaxies
25
4590
0
25
45
- The motions of asteroids
Preferential orbit- and spin orientations and their instabilities.
Poles
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- The orbital velocity about fast spinning stars
2
3 2 22
G I G M vv
r r c r
= +
The velocity v can be found out of :
v
Gyrotationof the star
Gravityof the star
Orbitmotion (if
circular)
Causes velocity-dependent orbit
precession
I is the stars inertia moment
is its angular velocity
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Explosion-free fast spinning stars and black holes
Tight compression by gyrotation forces a v =
Prediction attempt :
( )2 2a G mr Rc
R
r
At the surface:
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Prediction attempt : bursts of binaries
Matter from
companion
a v =
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- Mass- and light horizons of (toroidal) black holes
The graphic for the black holes horizons
at its equator level is mass-independent !
Hsradius Light horizon : limit surrounding
the black hole, where light remains
trapped by the black hole.
Schwarzschild radius Orbiting incoming massesdesintegrate but behind the light
horizon.
BHs spin rate
Mass horizon : limit surrounding
the black hole, where the orbits
reach the speed of light, and
matter disintegrate.
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-Self-compression of fast moving particles
by gyrotation
Gravity field deformation due to the gravitys speed retardation effect
Oleg Jefimenko
Prediction attempt : the high-speed meson lifetime increase
is caused by the gyrotation compression.
( )
( )
( )( )
2 2 2
3 22 2 2 2
3 1
,4 1 sin
G m v v c
p rr c v c
=
Pressure :
Between brackets
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But say : I use the Linear Weak Field
How to be accepted by Mainstream as a dissident?
Dont say : GRT is wrong;
I use Gravitomagnetism!
Between brackets
Approximation of theGeneral Relativity Theory
M. Agop, C. Gh. Buzea, C. Buzea, B. Ciobanu and C. Ciubotariu of
the Physics Department of the Technical University, Iasi,
Romania. They wrote many papers this way, accepted by
mainstream, and could boost their studies on superconductivity.
And refer to:
C l i
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Conclusions
- All these phenomena are explained in detail without any need
of relativity, spites the high speeds used.
- No gauges are used, the theory is not semi-empiric as the relativitytheory. Even the bending of the light and the Mercury issue are
purely deduced.
of part one
- Most of the explained phenomena are steady systems and dont
need any correction for the retardation of gravity.
- Only the calculation of the position of orbiting objects ortranslating objects at high speed can be improved by including the
retardation of gravity.
Current research
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Discovery : Relationship between
the suns spin and its geometry:
I found :
Frequency:
Current research
Coriolis Gravity and Dynamics Theory
Suneq 2
eq2c R =
The possible meaning is : the rotational speed of a body is
determined by its enclosed mass
graviton
Suneq
eq
G mvc R
=
Velocity:
Wh ld b h h i l h i ?
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2 22c a =
What could be the physical mechanism?
12Coriolis : let
1) A tangential graviton from particle 1 hits particle 2 directly
Let us consider particles as trapped light, that release gravitons:
Analysis
22 12a G m R=
12 22
G m
c R =12 2
G m
c R
=
In the case of outgoing gravitons that are tangential to the trapped light,
we get the case of the Suns spin rate explained.
a
and let:
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4 42c a =
3
4
a
2) A tangential graviton from particle 1 hits particle 2 indirectly
Coriolis :
From 1 :
( )2 2a=
22a G m R=
24 1a G m R=
In the case of outgoing gravitons that are spirally hitting the trapped light
we get Newtons gravity law !
Hence :
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3) A tangential graviton from particle 1 hits particle 1 indirectly
Are forces between particles just a Coriolis effect?
a a
5 55
F
5 52c a =
Coriolis : let
5 5F m a=
Newton :
Conclusions
- The relationship between the Suns spin and the Suns gravity is
not a coincidence.
- The Coriolis effect on trapped light, and tested by the Suns spin
fits with the Newton gravity.
of part two