An alternative to the concept of continuous medium

AbstractAn alternative, scalar theory of gravitation has been proposed, based on a mechanism/interpretation of gravity as being a pressure force: Archimedes’ thrust. In it, the gravitational field affects the physical standards of space and time, but motion is governed by an extension of the relativistic form of Newton’s second law. This implies Einstein’s geodesic motion for free particles only in a constant gravitational field. In this work, equations governing the dynamics of a continuous medium subjected to gravitational and non-gravitational forces are derived. Then, the case where the non-gravitational force is the Lorentz force is investigated. The gravitational modification of Maxwell’s equations is obtained under the requirement that a charged continuous medium, subjected to the Lorentz force, obeys the equation derived for continuum dynamics under external forces. These Maxwell equations are shown to be consistent with the dynamics of a “free” photon, and thus with the geometrical optics of this theory. However, these equations do not imply local charge conservation, except for a constant gravitational field.

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Electrodynamics of a Continuous Medium

Applications of Electrodynamics in Theoretical Physics and Astrophysics ◽

10.1201/9781315137575-6 ◽

2017 ◽

pp. 93-121

Author(s):

V. L. Ginzburg

Keyword(s):

Continuous Medium

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Variational theory for (2+1)-dimensional fractional dispersive long wave equations

Thermal Science ◽

10.2298/tsci200301023c ◽

2021 ◽

pp. 23-23

Author(s):

Xiao-Qun Cao ◽

Cheng-Zhuo Zhang ◽

Shi-Cheng Hou ◽

Ya-Nan Guo ◽

Ke-Cheng Peng

Keyword(s):

Porous Media ◽

Nonlinear Waves ◽

Inverse Method ◽

Wave Equations ◽

Continuous Medium ◽

Variational Principles ◽

Variational Theory ◽

Long Wave ◽

Potential Applications ◽

Fractional System

This paper extends the (2+1)-dimensional Eckhaus-type dispersive long wave equations in continuous medium to their fractional partner, which is a model of nonlinear waves in fractal porous media. The derivation is shown briefly using He?s fractional derivative. Using the semi-inverse method, the variational principles are established for the fractional system, which up to now are not discovered. The obtained fractal variational principles are proved correct by minimizing the functionals with the calculus of variations, and might find potential applications in numerical modelling.

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NMR Analysis Method of Gas Flow Pattern in the Process of Shale Gas Depletion Development

Geofluids ◽

10.1155/2022/3021326 ◽

2022 ◽

Vol 2022 ◽

pp. 1-7

Author(s):

Rui Shen ◽

Zhiming Hu ◽

Xianggang Duan ◽

Wei Sun ◽

Wei Xiong ◽

...

Keyword(s):

Flow Pattern ◽

Pore Pressure ◽

Shale Gas ◽

Gas Flow ◽

Continuous Medium ◽

Slip Flow ◽

Flow Patterns ◽

Transitional Flow ◽

Analysis Method ◽

Adsorbed Gas

Shale gas reservoirs have pores of various sizes, in which gas flows in different patterns. The coexistence of multiple gas flow patterns is common. In order to quantitatively characterize the flow pattern in the process of shale gas depletion development, a physical simulation experiment of shale gas depletion development was designed, and a high-pressure on-line NMR analysis method of gas flow pattern in this process was proposed. The signal amplitudes of methane in pores of various sizes at different pressure levels were calculated according to the conversion relationship between the NMR T 2 relaxation time and pore radius, and then, the flow patterns of methane in pores of various sizes under different pore pressure conditions were analyzed as per the flow pattern determination criteria. It is found that there are three flow patterns in the process of shale gas depletion development, i.e., continuous medium flow, slip flow, and transitional flow, which account for 73.5%, 25.8%, and 0.7% of total gas flow, respectively. When the pore pressure is high, the continuous medium flow is dominant. With the gas production in shale reservoir, the pore pressure decreases, the Knudsen number increases, and the pore size range of slip flow zone and transitional flow zone expands. When the reservoir pressure is higher than the critical desorption pressure, the adsorbed gas is not desorbed intensively, and the produced gas is mainly free gas. When the reservoir pressure is lower than the critical desorption pressure, the adsorbed gas is gradually desorbed, and the proportion of desorbed gas in the produced gas gradually increases.

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On the correctness of a phenomenological model of equilibrium phase transitions in a deformable elastic medium

European Journal of Applied Mathematics ◽

10.1017/s0956792500000760 ◽

1992 ◽

Vol 3 (2) ◽

pp. 181-191

Author(s):

A. M. Meirmanov ◽

N. V. Shemetov

Keyword(s):

Mathematical Model ◽

Continuous Medium ◽

Equilibrium Phase ◽

Elastic Solid ◽

Complementary Energy ◽

Structure Of Solutions ◽

Two Phase ◽

Pure Phase ◽

The Mathematical Model ◽

Uniqueness Of A Solution

In this paper we investigate the mathematical model of the equilibrium of a finite volume in ℝn (n = 1,2, 3) of a two-phase continuous medium, under the assumption that each pure phase is an isotropic elastic solid. The main results in this paper are:(i) the existence and uniqueness of a solution of this mathematical model;(ii) a discussion of the stress-strain law associated with the free energy of this two-phase continuous medium, which is multiple-valued due to the non-smoothness of the Gibbs potential (complementary energy);(iii) a description of the structure of solutions in plane strain.

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