C. Entropy and Templety
Entropy is a thermodynamic quantity which measures the diversity of individual states of a thermodynamic system. Physics in the classical limit states that the total entropy of an isolated system can never decrease. But real systems are not isolated and are not in equilibrium.
And what is principal : internal attractive force in nonequilibrium system can be the causation of entropy decrease.
Emergence of order breaks the equilibrium and causes generation of templates which are energetically more efficient, because emergent attractive force intervene on the thermodynamic random distribution. Energy decreases together with entropy fall of the emergent unit. Energy flows from the emergent formation to environment. In this way is this action well suited – following the law of energy conservation and homogenization.
What is more fundamental? Is it energy balance or entropy balance? Entropy decrease is escorted by energy transformation. Symetric homogeneous matter distribution changes due to local influence to a formation with lower energy. Some potential energy is needed to go back to initial homogenity and isotropy. Any kind of potential energy is the energy held by a system or formation because of the position of its constituents, more precisely position information. Any kind of potential energy is tied to a force, which is to overcome to restore starting homogeneous configuration.
So we see that any emergent attractive interaction can change a symmetry to a broken symmetry of emergent order. And position information of this asymmetry produces instantaneously entropy decrease. Attractive force is interlocked with entropic force and emergent attractive force is coupled with emergent entropic force. In this manner information of emergent matter templates is the source of entropic force, templety - the fifth fundamental interaction of matter in universe.
We conclude with : entropy of macro world realizations can decrease. The second law of thermodynamic is an idealization, analogous to 'point mass'.