暗物质与灵魂的科学依据

这个题目很有深度。是个非常“敏感”内容。

下面谈谈我个人的认知。

“暗物质”能解释“灵魂”吗？回答是；肯定的。一定的。原因是“灵魂”是“暗物质”生物磁场部分。如同每个人的“思维”也是应该属于“看不见”的暗物质能量，但不是人的全部。

“暗物质”是“光”单位外”全部物质的统称。

“灵魂”是暗物质中的一部分。是单一生物磁场的体现。“灵魂”对于每一个生物是“唯一”的综合体。“灵魂”生物的。

生物的“灵魂”的组合，是具有多种附属生物磁场。是一个功能性的组合体。如同；一只猫 一只天鹅 一头老虎 “一个人”或一个外星人或“其他生物”物种等等。

条件是；必须是“有智能”的生物品种。

有很多朋友问我“宇宙是平行”的。是不是在其他的宇宙空间还有我们。回答是；肯定的。有。

但“呈现的物种”未必是你“现在这个样”。开个玩笑；有可能你呈现的是个“恐龙”或是个“美人鱼”。

当科技发展到一定“水平”时。会揭秘很多很多大家不知道的现象和事物。

不管如何发展。 “人类”是智能生物是不会变得。“人类”是一个综合体生物是肯定的。“灵魂”是每个人的“唯一”，一个人只有一个。

物质的组成是由；看得见的物质+非看得见的物质组成的。这是不变的。“这可没有迷信”。

谈到这里。如有不妥，请原谅。

我所支持的E一分形时空从杨振宁的方法计算出的暗物质的比列与最近其他方法计算的值，基本一致，但方法更询单，看原文

Wave particle duality and dark energy

Continuing in the same vein, El Naschie proposes that Einstein’s famous formula E = mc consists of two parts. The first part is the positive energy of the quantum particle modeled by the topology of the zero set. The second is the absolute value of the negative energy of the quantum Schrödinger wave modeled by the topology of the empty set [3] (see above). The latter is the missing dark energy (actually dark energy and dark matter) of the universe accounting for 95.45 % of the total energy-matter in agreement with the findings from the Wilkinson Microwave Anisotropy Probe and the supernova cosmic measurement awarded the 2011 Nobel Prize in Physics. The dark energy of the quantum wave cannot be detected in the normal way because measurement collapses the quantum wave. Several recent attempts to detect dark matter with sophisticated detectors have failed [4]

No Dark Matter Detected Yet

(SiS62), which is potentially devastating for the standard model of cosmology that depends on postulates of dark matter and dark energy.

The Menger-Urysohn dimension and Hausdorff dimension of a random Cantor set are [o, f] [3]. The dimensions of the complement (gaps) are [-1, and 1 – f = f], as established above.

Raising both the f (points) and f(gaps) set to the Kaluza-Klein 5 dimensional spacetime gives f(volume) and 5f (boundary) and respectively equal to 4.5 % and 95.5 % of Einstein’s energy, the latter corresponding to dark energy/matter.

(Different estimates of dark matter and dark energy vary somewhat. According to the latest figure, dark energy plus dark matter constitute 95.1 % of the total content of the universe [5].)

The Kaluza-Klein 5 dimensional spacetime attempted to unify gravity with electromagnetism [6]. It originated with German mathematician physicist Theodor Kaluza (1885-1954) who extended general relativity to a five-dimensional spacetime to include the electromagnetic field. Swedish theoretical physicist Oskar Klein (1894-1977) later propose that the extra fourth spatial dimension is curled up, or compactified, in a circle of very small radius, so that a particle moving a short distance along that axis would return to where it began. This compactification of dimensions is now widely employed in string theories that attempt to give a realist explanation of why the universe looks and feels 4 dimensional (see Box). There may well be a more intimate relationship between the Kaluza-Klein spacetime and E-infinity spacetime, which El Naschie has not pointed to, though it is implicit in his work. Recall that the embedding dimension for E-infinity space-time of Hausdorff dimension 4 + f = 4. 236067977 is also 5, and the fuzzy tail of 0. 236067977 is the compactified (∞ - 4) dimensions. If we equate 0.236067977 = f with the sum of ordinary matter and energy that we can detect, and ask what percentage it is of the transfinite dimension of the Kaluza-Klein 5 dimensional spacetime, 5+ f, we get 4.5 %. In other words,

f/(5+ f) = .04721359…. ≈ 4.5 %

which gives 95.5 % dark matter/energy.

Thus, the compactified spacetime dimensions is likened to the super-particle of the universe, while the rest is the empty-set ‘halo’ and quantum wave that collapses as soon as it is measured. If that is the case, neither dark matter nor dark energy would be detected.

Strings and superstrings, current theories of the universe [7, 8]

String theory replaces point-like particles of particle physics by one-dimensional strings, and different types of observed elementary particles arise from the different quantum states of these strings. In addition, string theory naturally incorporates gravity, and is therefore a candidate for a ‘theory of everything’ or at least of quantum gravity. String theory requires extra spatial dimensions for mathematical consistency. In realistic physical models constructed from string theory, these extra dimensions are typically compactified to extremely small scales. This is a generalization of the Kaluza-Klein theory (see main text), which tries to reconcile the gap between the conception of our universe based on its four observable dimensions with the ten, eleven, or 26 dimensions that theoretical equations of string theories entail. Essentially, it is assumed that the extra dimensions are wrapped up on themselves into extremely small scales.

The earliest string model, the bosonic string, incorporated only the class of particles known as bosons (any number of which can occupy the same quantum state, unlike the other class of particle fermions, which cannot). Roughly speaking, bosons are the constituents of radiation, but not of matter, which is made of fermions. Investigating how a string theory could include fermions led to the invention of supersymmetry, a mathematical relationship between bosons and fermions. String theories that include fermionic vibrations are known as superstring theories, all are now thought to be different limits of a theory called M-theory. According to British theoretical physicist Stephen Hawking in particular, M-theory is the only candidate for a complete theory of the universe. Other physicists including Richard Feynman and Roger Penrose have criticized string theory for not providing novel experimental predictions at accessible energy scales and say it is a failure as a theory of everything.

Supersymmetry is a proposed extension of spacetime symmetry that relates two basic classes of elementary particles: bosons that have integer-value spin, and fermions with a half-integer spin. Each particle from one group is associated with a particle from the other group, called its superpartner, whose spin differs by a half-integer. No super-partners have yet been observed. The failure of the Large Hadron Collider to find evidence for supersymmetry has led some physicists to suggest that the theory should be abandoned.