Gravity space



Kalevi M. Sokka

Gravity space in answer to question:
‘What if graviton is a real particle?’


Real graviton inevitably leads to space of gravitons, to gravity space. At the moment the gravity space theory explains the function of gravitons in the space and the connection of other energy with the space.

The next task is to develop coherent mathematical formulation of gravity space self and of tied particles there. Another, huge task is to show physical and mathematical connection of fundamental interactions in the forming and functioning of structures in gravity space.

Theme Microsoft Word


Current affairs


Modern quantum physics as well as theory of relativity describe physical reality generally well, though each theory within its partly limited scope.

Both theories give also a few unclear or even wrong answers. Obviously some used physical assumptions and mathematical procedures lead finally to faults, and also prevent to unite the theories.

The remedy is to correct both theories to agree with the inside structure of universe formed by minor gravitons as in gravity space theory. After using the same internal construction of the space the theories might be coupled together in other ways, too.


LHC (Large Hadron Collider) has lately worked well; and some upgrades may follow.

Gravity space theory proposes various new particles to be found, mainly small and dark. However, the collider's scope is far from central area of dark particles; and the equipment has no established or sure means to notice dark matter and dark energy.


Gravitons are capable of mediating gravitational interaction, causing mass and like phenomena to gravitationally tied particles, and giving rise to the universal speed of fast particles (light). Gravitons participate in maintaining continuous, even accelerated expansion of the universe, and they imply existence of simple tied particles, which cannot be observed with WES-interactions.

Graviton flow together with gravitationally tied particles can perform all known gravitational functions. How graviton flow (space) primarily captures particles to the fast speed (light speed), and releases from, is one essential question to be cleared better; here may help progressive research of photons.


Novel practical applications associated with fast and slow motions are predicted by gravity space theory.

Slow motion changes place and direction of through going gravitons and thus changes effect of gravity, but generally only very minutely. The impulse becomes clearly noticeable when no friction dominates like towards spacecraft in outer space.

Graviton flow ties other particles into gravity space. Fast motion for lite particles begins as graviton flow is diverted with course transfer momentarily off from one direction. The same procedure could be used towards slow body (particle): part of graviton flow from one direction could be diverted off through pipe-porous or like structure ineffective. The dream, aim, is to use graviton flow itself to adjust slow motion in gravity space, both in level and in gradient gravity. Tied slow body (particle) can then be stopped, kept standstill or moved to desired direction with gravity.

Each tied particle creates and maintains its own private time; and each private time is connected to space via fast motion, ultimately via tiny gravitons. The physical concept of time becomes clear; time is connected to the motion of particles and further to the enlarging of gravity space (universe).


Light beam's motion through the universe can tell how gravity space i.e. gravitons transport light mixed with the account of how other tied particles affect the motion. Graviton bottom itself does not prevent light's motion but maintains it, keeps it ordered.

In central gravity space gravitons transport light (fast particles) at universal speed. Minor variations in traveling values can be caused by local changes in graviton density and in huge distances possibly by a change in the value of the expansion of the universe.


_ _ _ _ _
Mathematics of gravity space has to describe motion of particles on the bottom, which for graviton is emptiness, for fast particle a free graviton flow and for slow particle every-directional free graviton flow.

In central gravity space prevails, at the local speed  b, level every-directional straight graviton flow, which is in places however internally variable. In straight graviton flows also linear graviton density varies, specifically it is gradiently variable according to the amount of local tied energy en route; graviton size creates natural upper limit to linear graviton density.

Mathematical description of locally bent spacetime is a dim and imperfect depiction of physical reality, though it can give also exact numerical results. Differentiable curvature can be used to describe gradient gravity space mathematically, though 'pure' description of straight gradient graviton flows would be better, more exact and nearer to reality ...


Gravitational wave detectors, in front LIGO (Laser Interferometer Gravitational-Wave Observatory) and obviously future LISA (Laser Interferometer Space Antenna), generally  try to find large ‘perfect’ waves, which do not advance in gravity space.

To measure distances with locally sent perpendicular photon flows is useless; distances do not change. And perspective parts of simple advancing pulses do not pierce through the detector ends at all. Gradient parts of pulses do pierce into the detector, but compaction level in photon flows, though not in bare graviton flows, becomes equal to every direction at a place.

Advancing rhythmical changes in graviton flows might be best noticed by sending photons out from the detector towards the graviton source and using independent third observer to look at the receding photon flow from side.