A New Explanation of the Mechanism of Korean room temperature and ambientpressur

Thespace-time ladder theory reveals that dark matter is the root of the universe,and dark matter polarization produces contracted matter and expanding darkenergy.The formation mechanism of the LK-99 superconductor is the contractionof the matter structure caused by Cu2+ replacing the Pb2+(2) ions, and thecontraction of the matter results in the expansion of the dark energy, and theouter layer of the LK-99 material is an insulator, so the expansion of the darkenergy does not emanate, resulting in the electron and dark energy formation

Electron-pair-voidspace-time waves, such electron-pair-void space-time waves move freely in LK-99superconductors, forming superconductors.

Themost important superconducting mechanism: the contraction of the structure ofmatter induced by the substitution of Cu2+ for Pb2+(2) ions in the (e) diagramin the original article [1], which generates the corresponding quantum well andexpansion of dark energy (not presented and analyzed in the original article),and the excess dark energy due to the fact that lead apatite is theinsulator which is not emitted, and iscomposed with electrons: electron pair-void space-time waves.

file:///C:/Users/ADMINI~1/AppData/Local/Temp/msohtmlclip1/01/clip_image002.jpg

Figure(e) the side-view of the cylindrical column and the predicted superconductingquantum well.

Theformation of this superconductor is related to the polarization of the darkmatter in the structure, which is related to the contraction of the structureof matter caused by the substitution of Cu2+ for Pb2+(2) ions. Because of thepresence of dark matter, the contraction of matter inevitably produces anexpansion of dark energy. This expanding dark energy pairs with electrons ininsulators, forming electron pair-void space-time waves that move freely, whichis the superconducting mechanism of LK-99. This explanation, which includesmatter, dark matter and dark energy, is the basis of the wholesuperconductivity, and can explain not only one type of superconductivity, butalso two types of superconductivity, as well as the superconducting phenomenonof LK-99.

Allin all, the paper's explanations are all from the perspective of matter changes,jumping around the effects and implications of dark matter and dark energy in away that can be considered relatively continuous and complete. It is just thatthere is a bit of a jump and a bit of a tangent from quantum wells to thegeneration of superconductivity, because here dark energy and electron pairsare needed to form electron-pair-void space-time waves in order to move freelyand form superconductivity.

2.Calculation of the coherence factor [15].

Table1 Coherence coefficient of material Pb10-xCux(PO4)6O

The material Pb10(PO4)6O.	Material X(PO4)6O.	Coherence coefficient
Pb10(PO4)6O.	Cu(PO4)6O.
0.967483697	0.054767804	Coherence  coefficient1（KCC1）
0.942438083	0.997332284	Coherence  coefficient2（KCC2）
0.872049408	0.994000975	Coherence  coefficient3（KCC3）
0.52094034	0.976075878	Coherence  coefficient4（KCC4）
Pb9(PO4)6O.	Cu2(PO4)6O.
0.322880405	0.457242323	Coherence  coefficient1（KCC1）
0.085133835	0.806144492	Coherence  coefficient2（KCC2）
0.791496488	0.581858916	Coherence  coefficient3（KCC3）
0.252933382	0.322880405	Coherence  coefficient4（KCC4）
Pb10(PO4)6O3.	Ag(PO4)6O3.
0.999332848	0.018264058	Coherence  coefficient1（KCC1）
0.998814055	0.99970347	Coherence  coefficient2（KCC2）
0.997332284	0.999332848	Coherence  coefficient3（KCC3）
0.989343368	0.997332284	Coherence  coefficient4（KCC4）

Through Table 1 we know that this molecular formula is veryrigorous, and the coherence coefficient becomes lower when lead becomes 9, andwhen copper becomes 2. Therefore, the production process must be rigorous,otherwise, although it has the same material, the proportion is different andthe production process is different, which may lead to a big difference.

In addition, we have calculated that if more oxygen is addedto formPb10(PO4)6O3, it will have abetter coherence factor, and at the same time, by replacing copper with silver,a better superconductor will emerge: Pb10Ag(PO4)6O3. This is the best prediction of the theory of spacetime-stepsuperconductivity.

3. More calculations

Table 2 Coherence coefficients of more materials

The material Pb10(PO4)6O3	The material X(PO4)6O3	Coherence  coefficient
Pb10(PO4)6O3	Sn(PO4)6O3
0.99933285	0.03652202	Coherence  coefficient1（KCC1）
0.99881406	0.99881406	Coherence  coefficient2（KCC2）
0.99733228	0.99733228	Coherence  coefficient3（KCC3）
0.98934337	0.98934337	Coherence  coefficient4（KCC4）
Pb10(PO4)6O3	Fe2 (PO4)6O3
0.99933285	0.072995314661	Coherence  coefficient1（KCC1）
0.99881406	0.99525903389	Coherence  coefficient2（KCC2）
0.99733228	0.98934337	Coherence  coefficient3（KCC3）
0.98934337	0.95760060	Coherence  coefficient4（KCC4）
Pb10(PO4)6O3	Al4 (PO4)6O3
0.99933285	0.072995314661	Coherence  coefficient1（KCC1）
0.99881406	0.99525903389	Coherence  coefficient2（KCC2）
0.99733228	0.98934337	Coherence  coefficient3（KCC3）
0.98934337	0.95760060	Coherence  coefficient4（KCC4）

Through Table 2, we know that the coherence coefficients ofthe materials Pb10Sn(PO4)6O3， Pb10Fe2 (PO4) 6O3, Pb10Al4 (PO4 )6O3 are good. The above calculation is based on the conductivityto select, conductivity from small to large: tin < iron < aluminum <gold < copper < silver, the most conductive is silver, so, we choose: Pb10Ag(PO4)6O3 is the best superconductor. Next, we chose gold, aluminum,iron and tin to try in turn and found the above superconductors. If theexperimenters want to try more, they can read the paper [3].   

The reason for starting with the strongest conductivity isthat the Pb10(PO4)6O3 of the superconductor provides the best shell of an insulatorto ensure that the dark energy of the intrinsic electrons is not emitted, andthe intrinsic conductivity is chosen to be the strongest conductivity, which isto make the conductivity easier, and the combination of the two aspects makesthe best superconductor.

Suppose the above theory is not suitable for the realsituation, and we respect the already available molecular structure, we canhave the following calculations:

Table 3 Coherence coefficients ofexisting materials plus different metals

The  material Pb10(PO4)6O.	Material  X(PO4)6O.	coherence  factor
Pb10(PO4)6O.	Cu(PO4)6O.
0.967483697	0.054767804	Coherence  coefficient1（KCC1）
0.942438083	0.997332284	Coherence  coefficient2（KCC2）
0.872049408	0.994000975	Coherence  coefficient3（KCC3）
0.52094034	0.976075878	Coherence  coefficient4（KCC4）
Pb10(PO4)6O.	Fe(PO4)6O.
0.967483697	0.10937120838	Coherence  coefficient1（KCC1）
0.942438083	0.98934336808	Coherence  coefficient2（KCC2）
0.872049408	0.97607587756	Coherence  coefficient3（KCC3）
0.52094034	0.90544823749	Coherence  coefficient4（KCC4）
Pb10(PO4)6O.	Ni(PO4)6O.
0.967483697	0.072995314661	Coherence  coefficient1（KCC1）
0.942438083	0.99525903389	Coherence  coefficient2（KCC2）
0.872049408	0.98934336808	Coherence  coefficient3（KCC3）
0.52094034	0.95760059991	Coherence  coefficient4（KCC4）
Pb10(PO4)6O.	Zn(PO4)6O..
0.967483697	0.036522023058	Coherence  coefficient1（KCC1）
0.942438083	0.99881405524	Coherence  coefficient2（KCC2）
0.872049408	0.99733228366	Coherence  coefficient3（KCC3）
0.52094034	0.98934336808	Coherence  coefficient4（KCC4）
Pb10(PO4)6O.	Ge(PO4)6O.
0.967483697	1.8369095307E-16	Coherence  coefficient1（KCC1）
0.942438083	1	Coherence  coefficient2（KCC2）
0.872049408	1	Coherence  coefficient3（KCC3）
0.52094034	1	Coherence  coefficient4（KCC4）

From the calculations in Table 3, we know that Pb10Fe(PO4)6O, Pb10Ni(PO4)6O,Pb10Zn(PO4)6O, and Pb10Ge(PO4)6O are also goodsuperconductors, which means that within the insulator Pb10(PO4)6O, one can try to dope Fe,Ni, Zn, and Ge in addition to Cu.

[13. Conclusion]

The exploration of superconducting ring current flow mapping inboth directions similar to room temperature atmospheric pressurebio-superconductivity was reported by Quantum Physics Research in 2000, wheretwo groups of scientists in the US and the Netherlands, using superconductingcoils, demonstrated that current in a ring of superconducting wires could flowin both directions at the same time. This also exists in organisms wherebioelectric currents are reflected. This is a typical macroscopic quantumthree-spin phenomenon, rather than a similar inductive current or reactionforce principle. The reasoning is that when a ring-like body is tri-spinning,the markings on it cannot move in both positive and negative directions at thesame time along the face-spin, but because of the body-spin, the originalmotion in the positive direction is flipped over, and the markings move in theopposite direction.

And because the face and body spins are done in a very short time,the measurement is difficult to distinguish between them, and what is measuredcan only be the synthesis of 50% probability of each of them, so the markingsimilarly appears to be able to move in both directions at the same time, and withoutentanglement. This situation is only necessary for superconducting conditionsto be readily apparent as pure quantum triple spins; the two-way flow of thecurrent shown in the superconducting wire loop is also a manifestation of themacroscopic quantum phenomenon of this very principle, i.e., it is theprobability of electron triple spins in the superconducting clusters thatallows the current to appear to be able to flow in both directions at the sametime. This implies the existence of two different iterative states with unequalenergies (body spins versus surface spins), whereas an oscillation can beobserved.

The demonstration of this oscillatory phenomenon is considered alandmark in quantum mechanical experimentation.

Although thesuperconductivity of LK-99 has not yet been peer verified and reproduced, thetheory of space-time step superconductivity, has demonstrated that itscoherence factor is excellent. Not only that, the space-time stepsuperconductivity theory also predicts that Pb10Ag(PO4)6O3 is a bettersuperconductor than Pb10Cu(PO4)6O. If the verification is successful, not onlydo we get a better superconductor, but we also verify that the theory ofspace-time step superconductivity is the correct theory.

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