M.A. Reed, "Quantum Semiconductor Devices", in "Molecular Electronic Devices", F.L. Carter, R.E. Siatkowski, H. Wohltjen eds. North Holland, 1988.  Home/Search   Document Not in Database   Summary   Related Articles   Check

....Quantum Computing. WSI is already with us. It is the process of using the full surface of a slice of silicon crystal to contain one huge ULSI circuit. It is estimated by the mid 1990s [9] that it will be possible to place several million artificial neurons on a WSI circuit. Molecular Electronics [10] is the attempt to use molecules as computational devices, thus increasing computing speeds and allowing machines to be built with an Avogadro number of components. Nanotechnology is even more ambitious [11,12] aiming at nothing less than mechanical chemistry, i.e. building nanoscopic assemblers ....

....when a cell dies. One can imagine whole neural circuits being formed in this way, where differentiation would allow certain cells to modify their state depending upon the states of their neighbours. With future computing technologies (e.g. Wafer Scale Integration (WSI) 9] Molecular Electronics [10], Nanotechnology [11,12] and Quantum Computing [13] this kind of circuit growing will become possible, even necessary. WSI will be able to put ten million artificial neurons on a ULSI wafer by the mid 1990s [9] and at the other extreme, Quantum Computing promises to store a bit per atom, thus ....

M.A. Reed, "Quantum Semiconductor Devices", in "Molecular Electronic Devices", F.L. Carter, R.E. Siatkowski, H. Wohltjen eds. North Holland, 1988.

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M.A. Reed, "Quantum Semiconductor Devices", in "Molecular Electronic Devices", F.L. Carter, R.E. Siatkowski, H. Wohltjen eds. North Holland, 1988.

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