This post follows on from my previous one, Systemic Behaviour of Matter Particles, which was based on a hypothesis that describes physical reality in terms of the behaviour of the fabric of space and the interaction of its constituents. It defines the fabric of space as a medium of oscillating spherical and massless elements that give rise to matter particles as dynamics structures in spin motion, and it defines energy as the motion of those elements. Thus, a stable matter particles maintains spin and a quantum field around itself in the form of elements of space rotating around it in the direction of spin. In this post, I shall continue to explore those particles as thermodynamic systems and investigate their compliance with the laws of thermodynamics. Continue reading “Quantum Entropy”
This post is based on a hypothesis which describes physical reality in terms of the behaviour of the fabric of space and the interaction of its constituents. It is the subject of a book titled ‘Physical Reality – the fabric of space’. The hypothesis defines the fabric of space as a physical medium of discrete spherical elements permeating all space, and oscillating at an invariable period of Planck time. The diameter of an elements is the Planck length. As such, their frequency is constant and their amplitude of oscillation is independent of their frequency, and reflects temperature. The hypothesis defines energy as the motion of the elements of the fabric of space, be it oscillatory or curvilinear, and it defines matter particles as dynamic structures that form from those elements. Thus, quantum fields reflect the behaviour of the elements of the fabric of space in the immediate surroundings of the particles, which result from their interaction with the fabric of space. The hypothesis defines all other properties of matter particles, including electric charge and quantum spin number in terms of the mechanics of the elements of space forming the particles. However, it defines mass as the exposed background vacuum.
Considering individual matter particles as thermodynamics systems may seem a farfetched idea. The main reason is that the structure of subatomic particles has remained ambiguous and detached from the fabric of space with which it interacts. Based on the proposed hypothesis, it will become clear that subatomic particles are essentially systems the inner working of which is governed by the laws of thermodynamics. However, before I appeal to the laws of thermodynamics to define matter particles as thermodynamic systems, it is appropriate to define what is meant by a system and outline the different types of thermodynamic systems. Continue reading “Systemic Behaviour of Matter Particles”