Deep Unity of Classic and Quantum Physicsat the Space Thermostat Presence with Technical Applications

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Important Dates

Conference:

Apr. 22-24, 2019

Full Paper Due: Mar. 18, 2019

Abstract Due: Mar. 18, 2019

Audience Registration Due:
Apr. 22, 2019

Presentations of The Spring World Congress on Engineering and Technology (SCET 2017)

● Deep Unity of Classic and Quantum Physicsat the Space Thermostat Presence with Technical Applications
Author(s)
Mikhail Ivanov
Affiliation(s)
Central Institute of Aviation Motors
KEYWORDS
Classic and Quantum Physicsat, Space Thermostat Presence, Technical Applications
ABSTRACT
The paper demonstrates deep unity of classic and quantum physics at the space thermostat presence, which fulfilled near Earth space by the temperature T=2.73 K. Any studied natural or technical systems have closed heat contact with the space thermostat and some accompanied energy dissipation on its. The space thermostat registration is one of the great achievements in experimental physics and astrophysics during of a few last decades and presents itself the Cosmic Microwave Background (CMB). From the main thermodynamics position we consider the CMB as the additional external space thermostat with the known (no zero) temperature and include into account its influence on aerospace propulsion processes. The paper is devoted to united conservation laws of mass, momentum and energy for thermal technical processes. The united conservation laws are defined by intensive interaction of working medium and thermal radiation. In our modeling a radiate dynamics is described as motion of a continuous lightly movable medium with help of the field functions and the Euler variables. We show the soliton like solutions of a dispersive medium correspond to Schrodinger’s quantum solutions and demonstrate the atom hydrogen specters. One of the main questions of the paper is nature of entropy. We analyze carefully the first law of conventional thermodynamics and show the difference between quasi-static and dynamic entropy values. Here we begin from quasi-static and dynamic works of finite gas volume and present detail connection of continuer medium conservation laws with entropy value. By that only conventional quasi-static entropy is a state function. In the common case the full dynamic entropy isn’t a state function. In this case the entropy nature may be clearly demonstrated and estimated. In particular, entropy growth correspond total pressure losses and energy dissipation in the space thermostat. The paper contains typical technical examples for propulsion and energy productions at the space thermostat presence. Also there is shown the space thermostat presence should be included into account in any theoretical analysis (in thermo physics, astrophysics, high energy physics, biophysics, chemistry, and so on).