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Space time continuum

Should a fermion represent some special distortion, or knot, in the aether, spherical rotation allows it to move freely through the space-time continuum without getting entangled with its environment, which consists of the same stuff as the fermion. While rotating in spherical mode adhesion to the environment is rythmically stretched and relaxed as the fermion moves through space. This half-frequency disturbance of the wave-field, that supports the fermion in space, constitutes the effect observed as spin. [Pg.145]

To understand the appearance of spin it is necessary to consider a fermion as some inhomogeneity in the space-time continuum, or aether. In order to move through space the fermion must rotate in spherical mode, causing a measurable disturbance in its immediate vicinity, observable as an angular momentum of h/2, called spin. The inertial resistance experienced by a moving fermion relates to the angular velocity of the spherical rotation and is measurable as the mass of the fermion. [Pg.149]

It is possible to suggest that relativistic effects are operating within each wave-particle conceived as a four-dimensional space-time continuum, but that the equations of relativity should be inserted within those equations, descriptive of the properties of holographic matrices convolutional integrals and Fourier transformations. [Pg.126]

Any discussion of dimensions is incomplete without including time, since modern descriptions of our external reality refer to it as the "space-time continuum," or simply, space/time. Here is a concise explication of this idea ... [Pg.60]

Another big discovery of the early 20th century was the theory of relativity. One of the most novel discoveries was that particles moving with a speed near the speed of light behaved in different ways than more mundane objects like cars or apples. Notions such as time dilation , the twin paradox , and space-time continuum became well known. Many times, you do not have to bother with using relativistic equations for the description of particle movements, but in some cases you do, e.g. when trying to describe particles in big accelerators, and then one has to use the relativistic version of the Schrodinger equation, known as the Dirac equation. In fact, this is what is implemented in the computer codes I will describe later, but notations become very complicated when dealing with the... [Pg.4]

We divided the six concepts into three pairs, the first dealing with space, the second with time, and the third with the classic discrete/continuous dichotomy, already evident in the distinction between arithmetic and geometry. Placing the members of each pair of concepts on opposing faces of the cube in Figure 1, each face is in contact with each of the others except for the face directly opposite. Adjacent faces of the cube represent phenomena which require both concepts, can be explained by either concept, or lead to a new conceptual development subsuming both as in the space-time continuum of relativity theory. The concept of velocity requires both direction in space (3D) and duration in time (t). As seen in the previous section, certain failures encountered in the structural theory of organic chemistry can be explained either in spatial terms... [Pg.100]

This is the fundamental fourth dimension of the physical space-time continuum. [Pg.345]

Grunwald, S. 2006b. What do we really know about the space-time continuum of soil-landscapes. In... [Pg.732]

This space-time continuum differs from Euclidean space in that ds may be either positive or negative to differentiate between time-like and space-like... [Pg.97]

One of the many achievements of Einstein s general relativity was to geometrize gravitational theory. This geometrization consists in the first instance therein that one views the world of physical events as a space-time continuum in four dimensions. Such a continuum is, by definition, represented by a coordinate system. A coordinate system is simply a mapping of a class of world points on a class of four-fold numbers, or what may be called number points x, , x ). [Pg.321]

There is a certain dynamics directly in space-time continuum, which drives both a violation of the relativity and a variation of the constants. An example could be a consideration of our 4-dimensional world as a result of compactifica-tion with the radius of compactification dynamically changing. [Pg.245]

The Vanishing of Apparent Forces The Galilean Transformation The Michelson-Morley Experiment The Galilean Transformation Crashes The Lorentz Transformation New Law of Adding Velocities The Minkowski Space-Time Continuum How do we Gel E =... [Pg.104]

Pierce, G.E. Inflammation in nonheahng diabetic wounds the space-time continuum does matter. Am. J. Pathol. 159, 399-403 (2001)... [Pg.171]

Galilean-Newtonian postulates of space and time, in a single absolute space-time continuum. Therefore, this universal value is also-called the Universe line... [Pg.593]

Hermann Minkowski introduced the seminal concept of the four-dimensional space-time continuum (jc, y, z, ct). In our one-dimensional space, the elements of the Minkowski space-time continuum are events, i.e. vectors (x,ct), something happens at space coordinate x at time t, when the event is observed from coordinate system O. When the same event is observed in two coordinate tys-... [Pg.105]

Hermann Minkowski introduced the seminal concept of the four-dimensional space-time continuum (jc, y, z, ctY. ... [Pg.119]

Equation 20-19 provides a useful vehiele for introducing basic ideas and for testing difference schemes for use in forward simulation or time-marching, that is, in modeling events as they evolve in time for given parameters and auxiliary conditions. As before, we will solve Equation 20-19 by approximating it with algebraie equations at the nodes formed by a net of coordinate lines, but now, the time coordinate must also be discretized at uniform time intervals. Hence, we deal with numerical solutions in the x-t plane. We replace our space-time continuum with independent variables formed by a discrete set of spatial points x = i Ax, where i = 1, 2, 3,. . . , X discrete set of time points t = n At,... [Pg.378]

Sitter Willem tfe (1872—1934) Dutch astr. who proposed that the universe is an expanding space-time continuum with motion and no matter ( Astronomical Aspects of Theory of Relativity 1933) Skramovsky Stanislav (1901-1983) Czech phys. chem. and co-inventor of thermogravimetiy through his own-designed statmograph ... [Pg.468]

Event Point in space at a moment of time. The generalization, in the four-dimensional space-time continuum of relativity theory, of the concept of a point in a space as a geometric object of zero size. ... [Pg.44]

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See also in sourсe #XX -- [ Pg.145 ]



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