Future of the Computer

Computers that would be light based, meaning that they use light to carry out data to transform the silicon within the chip, by using specific algorithms and computation, would make data transfer making it far more efficient than the average electric based computers.  How this would be done though would depend on the type of materials you use for the quantum transfer between the input source(light) and the output material (atom that change on direct impact to quantum qubits). The structure is highly the most important thing for efficient processing as such because there is a lot of flexbility at the quantum level. Instead of just using the normal 1 and 0 in a quantum computer it is simultaneously 1 and 0, then there is detectors to analyze one and then immediately the other one changes, in laymen terms. However, I believe we should look more deeply into the phenomena  antiferromagnetism, on the quantum level. Antiferromagnetic materials occur commonly in transition metal compounds, especially oxides. Examples include hematite, metals such as chromium, alloys such as iron manganese (FeMn), and oxides such as nickel oxide (NiO). There are also numerous examples among high nuclearity metal clusters. Organic molecules can also exhibit antiferromagnetic coupling under rare circumstances, as seen in radicals such as 5-dehydro-m-xylylene. By focusing on the structure of antiferromagnetic,  antiferromagnetic interactions can lead to multiple optimal states (ground states—states of minimal energy). In one dimension, the anti-ferromagnetic ground state is an alternating series of spins: up, down, up, down, etc. Yet in two dimensions, multiple ground states can occur.Atoms in an optical lattice make an ideal quantum system in which all the parameters can be controlled. Thus they can be used to study effects that are difficult to analyze in organic crystals. They are currently being used for quantum information processing. Further research can lead to better control of the antiferromagnetic or even Synthetic antiferromagnets for better development in quantum computing. It would be better for processing on the manufacturing scale and probably cost efficient as well. Thus quantum computing can lead to a major distribution of cryptocurrency across the general consumer; a peer to peer money system that does proof-by-proof algorithms to confirm identity of a online money currency. With quantum computing it can speed up process and calculation ten-fold. It can harness the limitations we have today on normal computers. The thing is quantum computing already exists, there's not a fully functional long term one. If such efforts are done to control quantum computing we can have technology actually have enough power to produce 4-D like environments effortlessly. It can lead another breakthrough globally around the world, much like the.com bubble in the 2000's. 

Till next time, Wholeness and Balance to all.