Levitation for short distance transportation

CATTCC continues its research to discover and develop a transportation device that utilizes levitation as its methodology for mobility.

As of this writing, CATTCC’s research shows that the most plausible effort towards building a levitating device is by replicating Viktor Grebennikov’s device. There is, however, insufficient information to build such a levitating device. Nonetheless, something along this type of technology is necessary as a brand-new mode of transportation for today’s society. How can such a product be designed and built? It requires experimentation. Simplicity is the way of nature. Without having adequate information, such a product has to use experimentation as its source for building.

Polymorphic metals

There is new experimental work in polymorphic metals. Wikipedia has a page on polymorphism, as materials science. Another article: “Polymorphism in a high-entropy alloy” is found in nature.com, it describes polymorphism as the occurrence of different lattice structures in crystalline material, it’s defined as a critical phenomenon in materials science and condensed matter physics.

In the Nature article: “Polymorphism in a high-entropy alloy”, the article begins with: Polymorphism, which refers to the ability of a solid material to exist in more than one crystal structure, is widely observed in many materials including polymers, minerals and metals. The polymorphic transition is a well-known yet critical phenomenon in nature and surprisingly, polymorphs with identical compositions can have different physical, chemical and mechanical properties due to different structural characteristics, which have attracted considerable attention over the last few decades. Pressure and temperature are usually controlling parameters for inducing these transitions by altering the atomic and/or electronic structures and creating novel materials. For example, carbon can take on graphite and diamond under different pressures and temperatures.

This leads to an understanding that the entropy of metals will maintain consistency with electromagnetic properties. Our search is specific towards the molecular actions relating to electrogravitics.

Electrogravitics

In previous blogposts, the topic of electrogravitics was brought up. Electrogravitics is a relevant topic when searching the physics of subatomic makeup. There seems to be a relationship between non-ferrous elements, electrogravitics, and the cavity structure effect (CSE); in comparison to the entropy of ferrous elements and electromagnetic composition of subatomic action.

In a deeper look into electrogravitics and its impact on the subatomic physics aspect of the CSE, here is an excerpt from the book, ‘Rising from Unsustainable’:

For all those interested in the topic; theoretical physics is a fascinating subject. Spintronics, as explained in Wikipedia is:

   “Spintronics (a portmanteau – a linguistic blend of words – meaning: spin transport electronics), is the study of the intrinsic spin of the electron and its associated magnetic moment, in addition to its fundamental electronic charge, in solid-state devices. 



   “Spintronics fundamentally differs from traditional electronics in that, in addition to charge state, electron spins are exploited as a further degree of freedom, with implication in the efficiency of data storage and transfer. Spintronic systems are most often realized in dilute magnetic semiconductors (DMS) and Heusler alloys and are of particular interest in the field of quantum computing.” 

In the theory of spintronics, the spin of the electron is an intrinsic angular momentum. That is separate from angular momentum due to its orbital motion. Then, the theory claims the magnitude of the projection of the electron’s spin along an arbitrary axis is ½ħ (one half times Planck constant), implying that the electron acts as a Fermion by the spin-statistics theorem (relates the intrinsic spin of a particle - angular momentum not due to the orbital motion but, to the particle statistics it obeys).

The argument is a claim that an electron’s spin is NOT arbitrary. Rather, it follows a distinct pattern along its linear path at the speed of light. The purpose of adding the book’s excerpt is pointing toward the discovery of the sub-atomic movement path in particle physics. This topic of electrogravitics also accents gravitational control, for which these blogposts are based; the future for transportation.

Levitation

This research relating to levitation considers properties of electrogravitics. Experimentation with certain non-ferrous elements of crystal polymerization in lattice structure and the compression of CSEs, will likely reveal a subatomic electrogravitics action; rather than electromagnetic. This would seem to be where levitation action can be found.

In the process of elimination through experimentation, a quick look at Britannica.com shows hexagon shaped minerals. There are only a few minerals whose internal structure is classified under the hexagonal system. They include calcite, dolomite, quartz, apatite, emerald, and ruby. Their structures allow light to travel through the crystals at difference speeds and at different angles. These minerals are hexagonal structures.

Is there any necessity to build a hexagonal shaped crystal? The requirement for CSEs is a cavity structure. Building a configuration of crystalized polymers with chitin is necessary for the honeycomb shape in forming a cavity structure. It is only the cavity within the structure where the CSE takes place.

The question becomes: how to assemble an egg carton type of configured structure.

The next question is: can a device be built to contain and be built to manipulate a CSE? Can such a device lift its own weight? Can two or more structures be stacked to multiply the CSEs? Can such a device be assembled and built to carry heavy loads?

In the process of experiment implementation, an analysis of chitin molecule for structural manipulation is a necessity. Now to build an apparatus with a cavity structure.