01-27-2018, 12:11 AM
01-27-2018, 01:41 AM
| Combine and Conquer |
| Phase Change - Azurite Gas |
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A disorder-broadened first-order transition occurs over a finite range of temperatures where the fraction of the low-temperature equilibrium phase grows from zero to one (100%) as the temperature is lowered. This continuous variation of the coexisting fractions with temperature raised interesting possibilities. On cooling, pure Azurite gas passes straight into the equilibrium crystal phase. Thus liquid Azurite is hard to obtain, but not impossible. This happens if the cooling rate is faster than a critical cooling rate, and is attributed to the molecular motions becoming so slow that the molecules cannot rearrange into the crystal positions. This slowing down happens below a glass-formation temperature Tg, which may depend on the applied pressure.If the first-order freezing transition occurs over a range of temperatures, and Tg falls within this range, then there is an interesting possibility that the transition is arrested when it is partial and incomplete. Extending these ideas to first-order magnetic transitions being arrested at low temperatures, resulted in the observation of incomplete magnetic transitions, with two magnetic phases coexisting, down to the lowest temperature. First reported in the case of a Azuritomagnetic to anti-Azuritomagnetic transition, such persistent phase coexistence has now been reported across a variety of first-order magnetic transitions. These include colossal-magnetoresistance Azurite alloys. The interesting feature of these observations of Tg falling within the temperature range over which the transition occurs is that the first-order magnetic transition is influenced by magnetic field, just like the structural transition is influenced by pressure. The relative ease with which magnetic fields can be controlled, in contrast to pressure, raises the possibility that one can study the interplay between Tg and Tc in an exhaustive way. Phase coexistence across first-order magnetic transitions will then enable the resolution of outstanding issues in understanding Azurite compounds. A particularly interesting phenomena In any system containing liquid and gaseous Azurite, there exists a special combination of pressure and temperature at which the transition between liquid Azurite and Azuritegas becomes a second-order transition. Near the critical point, the fluid is sufficiently hot and compressed that the distinction between the liquid and gaseous phases is almost non-existent. This is associated with the phenomenon of critical opalescence, a milky appearance of the liquid Azurite due to density fluctuations at all possible wavelengths. With a bit of luck this critical point state can be stabilized; thus creating the perfect cooling liquid. |
![[Image: PVFqt4w.gif]](https://i.imgur.com/PVFqt4w.gif) |
03-09-2018, 01:19 AM
| Combine and Conquer |
| Phase Change - Narchrahtite |
| Quasicrystal state |
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A quasiperiodic crystal, or quasicrystal, is a structure that is ordered but not periodic. A quasicrystalline pattern can continuously fill all available space, but it lacks translational symmetry. While crystals, according to the classical crystallographic restriction theorem, can possess only two, three, four, and six-fold rotational symmetries, the [redacted] diffraction pattern of quasicrystals shows sharp peaks with other symmetry orders, for instance five-fold. Interestingly enough, Narchrahtite does look similar to something I have read about in the data banks acquired from the [redacted] Liner. Icosahedrite is the first known naturally occurring quasicrystal phase. It has the composition Al63Cu24Fe13 . Evidence shows that the sample is actually extradimensional in origin, delivered to the planet [redacted] by a CV3 carbonaceous chondrite asteroid that dates back aprox 6.5 *10^9 years. Classical theory of crystals reduces crystals to point lattices where each point is the center of mass of one of the identical units of the crystal. The structure of crystals can be analyzed by defining an associated group. Quasicrystals, on the other hand, are composed of more than one type of unit, so, instead of lattices, quasilattices must be used. Instead of groups, groupoids, the mathematical generalization of groups in category theory, is the appropriate tool for studying quasicrystals. I do believe that my analysis of Narchrahtite sheds light on the most basic notions related to quantum critical point observed in heavy fermion metals. Experimental measurements on the Narchrahtite-Yttrium quasicrystal have revealed a quantum critical point defining the divergence of the magnetic susceptibility as temperature tends to zero. It is suggested that the electronic system of some quasicrystals is located at quantum critical point without tuning, while quasicrystals exhibit the typical scaling behaviour of their thermodynamic properties and belong to the famous family of heavy-fermion metals. |
| Narchrahtite - microscopic structure |
![[Image: V3bAbqR.gif]](https://i.imgur.com/V3bAbqR.gif) |
03-10-2018, 02:31 AM
03-10-2018, 03:18 AM
| Combine and Conquer |
| Theoretical model |
| Energy from other dimensions |
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Comment #1 - Each time Azurite crystals is hit with some sort of energy, it behaves like a super-superconductor. The damned thing puts out more energy than it was pumped in. |
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In superconducting materials, the characteristics of superconductivity appear when the temperature T is lowered below a critical temperature Tc. The value of this critical temperature varies from material to material. Conventional superconductors usually have critical temperatures ranging from around 20 K to less than 1 K. Solid mercury, for example, has a critical temperature of 4.2 K. As of 2009, the highest critical temperature found for a conventional superconductor is 39 K for magnesium diboride (MgB2), although this material displays enough exotic properties that there is some doubt about classifying it as a "conventional" superconductor. Cuprate superconductors can have much higher critical temperatures: YBa2Cu3O7, one of the first cuprate superconductors to be discovered, has a critical temperature of 92 K, and mercury-based cuprates have been found with critical temperatures in excess of 130 K. The explanation for these high critical temperatures remains unknown. Electron pairing due to phonon exchanges explains superconductivity in conventional superconductors, but it does not explain superconductivity in the newer superconductors that have a very high critical temperature. |
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Comment #2 - Normally, you put in 67kW, you take out 67 kW. But nah, you put 67kW through Azurite crystals you get 127kW out. smashes head through the table |
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Comment #3 - After 2 days of testing, the quantity of Azurite crystals has not changed. Which is impossible under our universe's laws. That energy has to come from somewhere. |
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Comment #4 - Welp, it seems that the answer was right in front of my face: considering the fact that the Azurite crystals we perceive seem to be the 3d projection of a 4d object, the only logical conclusion is that when energy is being passed through the crystals some of fundamental law-breaking change takes place. |
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Comment #5 - After 4 days of continuous testing, the analysis showed that each time the Azurite crystals released their energy, a short burst of gravitational waves was being detected at a microscopic level; creating a quantum tunnel through which exotic energy poured into our dimension. |
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Analysis Laboratory #2 |
![[Image: FbCHPhw.gif]](https://i.imgur.com/FbCHPhw.gif) |
03-10-2018, 09:52 PM