i need abstract for moletronics an invisible technology can you please send to muy mail
I try to download a report on "molectronic an invisible technology" but I failed.please send me report on above topic by mail"akashgoyal141095[at]gmail.com".
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As a scientific pursuit, the search for a viable successor to silicon computing technology has aroused considerable curiosity in the last decade. The latest idea, and one of the most intriguing, is known as molecular computers, or moletronics, in which individual molecules serve as switches, "quantum cables" a few atoms thick serve as wiring, and the hardware is chemically synthesized from Bottom up. The central thesis of the moletrónica is that almost any chemically stable structure that is not specifically prohibited by the laws of physics can in fact be constructed. The possibility of building things atom by atom was first introduced by Richard Feynman in 1959.
An "assembler", which is little more than a submicroscopic robotic arm can be built and controlled. We can use it to secure and position the compounds in order to direct the precise place where the chemical reactions occur. This general approach allows the construction of large objects, atomic precision, initiating a sequence of controlled chemical reactions. For this to work as we wish, each assembler requires a process to receive and execute the set of instructions that will dictate his actions. Over time, molecular machines could even have on-board, high-speed RAM and slower but more permanent storage. They would have communications and power supply capacity.
Moletronics is expected to touch almost every aspect of our lives, to the water we drink and the air we breathe. Experimental work has already resulted in the production of molecular tweezers, a transistor of carbon nanotubes and logic gates. The theoretical work is progressing as well. James M. Tour of Rice University is working on building a molecular computer. Zyvex researchers have proposed an exponential assembly process that could improve the creation of assemblers and products before they are even simulated in the laboratory. We have even seen researchers create an artificial muscle using nanotubes, which may have medical applications in the nearer term.
Teramac has the ability to perform 1012 operations in one second, but it has 220,000 hardware defects and has still performed some tasks 100 times faster than the single processor. The defect-tolerant computer architecture and its implications for moletronics is the latest in this technology. So the fact that this machine worked suggested we should take some time and learn about it. Such a "fault-tolerant" architecture through the lectern could bridge the gap between the current generation of microchips and the next generation of molecular scale computers.