Quanta-chain

During lengthening process of a free quantum of matter, its ends may come in contact with other quanta of matter, which happens to be in its spatial dimension. Under such condition, the lengthening process of the quantum of matter is restricted, in the direction of the second quantum of matter. Matter-contents of the quanta of matter come in direct contact in the same spatial dimension. As magnitude of adhesion between their matter-contents (across their perimeters) is less than the magnitude of adhesion within each of their matter-contents, their matter-contents cannot merge. [Adhesion between contacting quanta of matter is due to their continuous movements and changes of directions]. If a lengthening-quantum of matter encounters other quanta of matter in other spatial dimensions, it will not be restricted in its growth. Adhesive effort between matter-contents of two quanta of matter (in direct contact) tends to keep the quanta of matter, pressing into each other. If the direction of this adhesive effort is perpendicular to the body of any one of the quanta of matter, they will remain in an equilibrium state. Should the direction of adhesive effort differ from being perpendicular to the body of any one of the quanta of matter, it may be considered as combination of two resolved components. One component, which is perpendicular to the body of any one of quanta of matter, keeps the quanta of matter pressed into each other. While, other component of adhesive effort tends to move one quantum of matter (whose body is at an angle to the body of the other) towards one end of the other quantum of matter. This is the most primary instance of induced motion in nature. Adhesive effort between two quanta of matter (in direct contact) tends to move either one or both of quanta of matter, towards each other’s ends, where together the quanta of matter form a junction and attempt to mutually turn their bodies to bring their (single-dimensional) bodies in a straight line. In this manner, free quanta of matter in space tend to form single-dimensional chains. Due to frequent ruptures of these quanta-chains and availability of free quanta of matter (in space) to migrate into ruptured 1D quanta-chain, there are far too many quanta of matter in any single dimensional quanta-chain. Excess number of quanta of matter in a quanta-chain compels all constituent quanta of matter in the quanta-chain to be held at reduced lengths in their single-dimensional status. Tendency of quanta of matter in the chain, to grow in length, keeps all constituent quanta of matter in quanta-chains under compression from their ends. Normally (in current state of universe), quanta of matter in a quanta-chain are maintained at the brink of their growth into second spatial dimension. Should a discontinuity develop in the quanta-chain, inherent property of constituent quanta of matter enable quanta-chain to grow in length. Thus, it becomes an inherent property of quanta-chains to grow (lengthen) into any discontinuity in its spatial dimension.