Name: Anonymous 2019-08-19 10:49
I have cracked the code and hacked the Universe. I have developed my own RTSC. Merely put pieces of the puzzle together with a little reverse engineering to discover the missing details. This is not a joke. Total cost to develop my samples was around $9500, but most of that went into buying a used desktop vacuum sputtering machine for PVD. I'm almost shaking in excitement. I'm not the first to achieve this, but perhaps the first private individual to do so. I'm probably going to destroy my samples and keep quiet about this beyond this thread. Why cast pearls before swine, etc.
Now, superconducting substrates belong to the class of materials known as quantum liquids, and sit in between insulators and regular conductors in terms of their electron gap distance within the atomic lattice of the substrate. Lowering them to their critical temperature induces superconductivity, which occurs when Cooper pairs of electrons form (a macroscopic quantum state) and then flow through the lattice like a liquid, without bumping into each other which would cause decoherence, and thus have zero resistance. Interestingly, black holes are quantum spin liquids (as follows from N=4 supersymmetric Yang-Mills theory and the AdS/CFT correspondence) and so provide an interesting model with which to reason about superconductors. Turns out that black holes become superconductive when you place them inside of a box that is in thermal equilibrium with the rate at which the black hole emits Hawking radiation and then increase the angular momentum or spin, which will lower the black hole's temperature or entropy to near zero. Then there's research in the last two years that has discovered that bilayer graphene sheets rotated approximately 1.1 degrees stacked on top of one another become superconducting at higher temperatures (although still only at around 150 degrees kelvin). In a recent paper, it was demonstrated that rotating the graphenes sheets into the Moire pattern actually lowers the entropy of the atomic lattice. Then there's this year's discovery of lanthunum hydride becoming a room temperature superconductor at high pressures (like 2 to 3 million atmospheres). Guess what? Increasing the pressure in a system while maintaining the same temperature lowers its entropy proportionally.
It would seem lowering the entropy is what's key to inducing superconductivity and temperature is merely one axis along which to achieve this. Maximum entropy is the same thing as exact equilibrium, and this would intuit that what we're after is something that places our quantum liquid substrate into a state of high disequilibrium in one or more degrees of freedom.
Now, superconducting substrates belong to the class of materials known as quantum liquids, and sit in between insulators and regular conductors in terms of their electron gap distance within the atomic lattice of the substrate. Lowering them to their critical temperature induces superconductivity, which occurs when Cooper pairs of electrons form (a macroscopic quantum state) and then flow through the lattice like a liquid, without bumping into each other which would cause decoherence, and thus have zero resistance. Interestingly, black holes are quantum spin liquids (as follows from N=4 supersymmetric Yang-Mills theory and the AdS/CFT correspondence) and so provide an interesting model with which to reason about superconductors. Turns out that black holes become superconductive when you place them inside of a box that is in thermal equilibrium with the rate at which the black hole emits Hawking radiation and then increase the angular momentum or spin, which will lower the black hole's temperature or entropy to near zero. Then there's research in the last two years that has discovered that bilayer graphene sheets rotated approximately 1.1 degrees stacked on top of one another become superconducting at higher temperatures (although still only at around 150 degrees kelvin). In a recent paper, it was demonstrated that rotating the graphenes sheets into the Moire pattern actually lowers the entropy of the atomic lattice. Then there's this year's discovery of lanthunum hydride becoming a room temperature superconductor at high pressures (like 2 to 3 million atmospheres). Guess what? Increasing the pressure in a system while maintaining the same temperature lowers its entropy proportionally.
It would seem lowering the entropy is what's key to inducing superconductivity and temperature is merely one axis along which to achieve this. Maximum entropy is the same thing as exact equilibrium, and this would intuit that what we're after is something that places our quantum liquid substrate into a state of high disequilibrium in one or more degrees of freedom.