fields of catchable chains

Chains of wave particles are acting like a single wave particle. Because their motion isn't disturbed, the chain has also a mass of zero. A chain of sticking wave particles is called field line. This is the most common occurrence of wave particles, more than single free moving or clusters of wave particles.

Each field has at least one field lines producing source.

Usually field lines don't interact with each other or with other twisted strings or clusters. Only if the protecting tail is not moving in front of the twisted string or a string is untwisted, they interact. In a high energy environment like the chain producing source parts of chains can be melt together to cluster cores.

field lines

If two wave particle are bound together, their orientation determines what happens. They have only two possible binding points: Moving the same direction or oscillating and stopping. The first one is the seed of a chain and the last one is known as a Meson, an instable composed particle of a quark antiquark. If a meson is falling apart, this is called pair production and it makes sure, that all links of a sticking wave particles are moving in one direction.

Through the eyes of twisted string theory, there is an unstable binding of two twisted strings, which have an opposite spin direction.


After the breakup of the pair of twisted strings each strings is untwisted for a short time. If there is a magnetic field, the strings are distracted by the field lines and starting to coil. A cloud chamber reveals this process.

image License: CC-BY-SA 3.0, author: Ivan Baev

The spin of every link in a chain of twisted strings has the same direction, because if a twisted string with an opposite spin direction is attached, it will be drop off.

The binding of the links needs a lot of energy. The chains are produced in stars.


An earth magnet didn't produce chains of twisted strings. But if it loses a string, the empty traps will catch a new one, which is coming from our sun.

image License: Punlic Domain, author: NASA

magnetic and electric field lines

Only twisted strings have a feature to catch field lines. A cluster needs an empty sling without an escapement spinning string. Only a sling can catch a field line. After catching it, the whole chain starts half spinning and oscillating, the motion of the field line stops. But the oscillation pushes or pulls the cluster trap. The cluster becomes a magnet.

The escapement spinning string can also catch a field line. But because of the extreme spinning the connection is just temporary and just the direction but not the motion changes. This is electric conducting.

Because the sling and the escapement are orthogonal, also a magnet field and a electric field are orthogonal.


[A] The twisted strings like to be chained, because the tail is disturbing other twisted strings flying ahead and is catching them. The sizes of the chain links can differ, because the velocity of all twisted strings is speed of light.

[B] If at least one chain link is trapped in a cluster, every link of the chain starts to oscillate and the whole chain is stopping.

The motion of a trapped field line is equal to the motion of the trap.

The endings of a trapped field line differ. The ending determines if another cluster is pushed or pulled. [B 1] is pulling, while [B 2] is pushing.

jumping field line


distortion enhanced field

The field lines don't interact with wave particle or clusters, because of the "collision protection system" of the dragging string motion. But the strings of the last link of the field line does slightly disturb the motion of a passing particles.


The distortion is extremely weak. If the field line is stationary, the effect is augmented, because the probability of multiple contacts is increased.

The result is weird. Not length of the field line or the quantity of links causes an effect, but only the quantity of the field lines is the important factor, that is responsible for the distortion. This yields to the strange behavior of the field. If a distortion of the field tears apart some field lines, the distortion can multiply the number of field lines and can multiplying the field effect.


That produces the illusion, that the distortion of the field is a source of this field, but the original force of the distortion field is somewhere else.

It is the escapement string, that has the task to tear apart the field lines.


Gravity is a distortion enhanced field, where every cluster with escapement spinning strings will cause an distortion and create the illusion, it is producing a gravity field.

The field of gravity is the mother of all eletcromagentic fields. The centre and the source of the field is a star. A star produces field lines and also catch them.

A planet or other cluster of mass are disturbing the field of gravity. Because of the effect of the distortion enhancement it seems like the field of distortion belongs to the massive object.

A magnetic field is also a distortion of the gravity field but it collects a lot of short field lines of the field of gravity. It exponentiates the effect of distortion enhancement and therefore the force can be much greater than the force of the mother field.

infrared field

The infrared field doesn't contain chains. Its a field of infrared embossed string, that are just temporary attached to clusters and are exchanging heat.