Stable biton

Inertial properties of distortion-field around a biton guide 3D matter-cores of its constituent photons to synchronize their movements with each other. They will move at the same linear speeds and spin at the same frequency in phase with each other. Disc-planes of 3D matter-cores of these photons will always coincide with each other. Mean circumference of a biton is equal to one wave-length of its constituent photons. A cloudy set of half-rings may be assumed as visual image of a biton. Gap between the half-rings indicate positions of photons when planes of their 3D matter-cores coincide with the plane of biton. External pressure on a biton tends to push constituent photons towards each other and thus reducing mean diameter of the biton. Overbearing between inertial-pockets of the photons tends to reduce their linear speeds and pace way for the photons to reduce their 3D matter-contents. Reduction of 3D matter-content of a photon lowers its frequency. Reduction in frequency of constituent photons of a biton increases mean circumference of the biton and thus making it larger in size. Therefore, external pressure on constituent bitons of a 3D matter-body causes its expansion in size and loss of 3D matter-content from it. This phenomenon is heating. A 3D matter-body is at its highest 3D matter-content level (coolest) and smallest in size when external pressure on it is least (in free space). For the same reason, inner core of all macro bodies are at much higher temperature than its surface and may be in different physical states. Each photon has a primary electric field in its circular plane. Combinations of primary electric fields of constituent bitons in superior 3D matter-bodies produce their resultant electric fields. Arrangements of primary / resultant electric fields in proper array produce a magnetic field.