The long-term data storage problem.
When we think about long-term data storage. That resists electromagnetic radiation, magnetic fields, and physical damage, we can think about things like films, where data is stored in the form of barcodes. Those barcodes can be stored. In the microfilm, each frame can be protected using armored glass. The computer can read that data using the microfilm reader. If there is a CCD camera mounted in the system. The system can use a projector and the film. That barcode travels through that system. The computer can have a simple operating system that allows it to read those barcodes and then decode that data into the computer. The barcodes can have like two thin lines, which represent zero, and one wide line can represent one. The system can have certain code that tells the end of the program.
Or code sequence ends. But if the system uses a geometrical form. like squares, triangles, crosses, and circles. That thing makes creating the new type of quantum communication possible. The square can be one, the triangle can be zero, and the circle can be the operator that tells that the code line or program’s code is ended. Basically, those geometrical shapes that the computer reads and transforms into programs can be letters. B can be 1, A can be 0. The system can take any letter group from the alphabet. The system requires marks to separate two zeros and show when the program ends. That makes the data system faster.
The ability to store data in chemical form can be a game-changing way to store information. But can there be a practical way to make that thing? Sometimes futurologists say that they will store data in the DNA. molecule. And that is one of the most exciting ways to store data. Artificial cells can transmit that data into computers using bioluminescence, which flashes are ones and zeros. Or those artificial cells can send electric impulses to a computer. And that is one way to store information. But there is another way. To make chemical data storage. That doesn’t require the ability to code DNA molecules.
One way is to use carbon-chloride molecules. Those chroride-carbon chains are flat. And there are ways to make that thing.
1) The choride-carbon chain is the one. And the intermediate is zero. Those molecules can be put under the glass. And then the system can read those molecules. The length of the intermediate determines. If there is a zero or a break.
2) The system can involve two types of molecules. The first molecule is one, and the other one is zero. Those molecules can be stored under the glass plates, and the microscope reads data, which is stored in those molecules.
3) The system could be faster if there were different molecules that show the zeros and ones. And if there is a molecule that shows the break. Or the endpoint of the code. There should be a separator that determines. When there are two zeros after each other. The system must also be separated. If the power is shut down or if there is only a break when the system waits for a new program. That makes those systems faster, and they don’t require a clock as much as electronic binary systems.
A simple way to store data is to use images or a series of geometrical images to store and transmit data. The geometrical forms can be 1, 0, beak, and the end of the code line. Chemical and optical ways to transmit data. This is the thing. That makes data transportation safe. The data that is stored in the form of molecules can be transported using protein tapes.
