Lego Universe - QUNM

Magnetic

Magnetic

Other than the non-circularity of the magnetic, magnetic act the same way as charge-charge interactions the forces just sum differently because the magnetic 'arc' can be manipulated. Magnetic and charge also show a space filling model as the magnetic attempts to fall back into the charge quanta.    

Figure 16: Magnetic field lines conglomerating into a large field line through interaction of magnetic quanta traveling in the same direction.

Above is a picture of how magnetic, conserving absolute momentum, change potential and expand. Such an occurrence might happen when two magnetic fields interact passing in the same direction. The momentum of the magnetic remains constant so the magnetic quanta progress along their path slower as expansion happens.

Below on the right if two magnetic fields interact resulting in motion in the same direction the magnetic has either the option seen above where an expansion combines the magnetic field lines, or the same sort of acceleration as seen in the charge quanta with spin the same direction – the accelerate into each other, yet must maintain speed so they pop-roll apart in a low force exchange. That is to say without angle effects magnetic lines of quanta in the same direction may either expand (as above) or pop off each other – with a low intensity of force. Whereas, in the right hand path in Figure 17 below if the result is two magnetic accelerating towards (into) each other, the two opposing directional magnetic ends meet (as in the ends of the quanta) there is a large force stopping each other dead, as momentum is conserved they cross (or a very sharp turn is made – which is a huge local torque) and expand as like magnetic did above, as now they are headed in the same direction; or, the two field lines will pop apart with a large force (if the force can move the objects generating the magnetic apart).

The torque of linearizing magnetic quanta must be applied repeatedly to the local magnetic passing through, and a reduction of energy favours the magnetic into curvature.

Figure 17: The effects of interaction of the magnetic quanta at an angle. On the right the two interacting magnetic quanta rotate to the same direction. Where, it may act like figure 16, or it may 'pop' apart with low force. On the left the magnetic quanta rotate to the opposite direction which causes then to abruptly stop when hitting each other's end. These then line up from head to tail to complete a single magnetic field line as per Figure 18.

Below, Figure 18, is an instance where themagnetic did not pop apart with a decent force to move the magnetic producingobjects and the magnetic field lines conglomerate: the right hand path of thediagram above.    

Figure 18: The formation of a single magnetic field line from two. The magnetic quanta accelerate into each other and stop dead when they hit each other's ends. This causes a high torque as the lines conserve absolute momentum through opening the ring and carrying on.

Figure 19: The concept can show that the formation of concentric rings would naturally occur. Magnetic is still at potential to charge. While, it follows its own acceleration to find the potential at which it will sit.

A wire with moving charge (under potential) has concentric rings of magnetic field as portrayed in Figure 19. This can again be traced to the electron being a right handed particle where the back charge field strings have bent towards the front. This gives the classic right hand rule of magnetic field in a wire with moving charge. In the above diagram electrons are flowing into the page through the wire (black spot).