Title :
Quantum-dot cellular automata: an architecture for molecular computing
Author :
Blair, Enrique P. ; Lent, Craig S.
Author_Institution :
Dept. of Electr. Eng., Notre Dame Univ., IN, USA
Abstract :
The quantum-dot cellular automata (QCA) paradigm is a revolutionary approach to molecular-scale computing which represents binary information using the charge configuration of nanostructures in lieu of current switching devices. The basic building-block of QCA devices is the QCA cell. Electrostatic interaction between neighboring cells allows the design of QCA wires, logic devices and even simple microprocessors. The geometry of molecular six-dot QCA cells enables the clocking of QCA devices via an electric field generated by a layout of clocking wires. Thus, precise control over the timing and direction of data flow in QCA circuits is possible. The design of QCA circuits now lies not only in the logic structure of the cells, but also in the layout of clocking wires. We discuss the clocking of QCA devices and connect layout to architecture.
Keywords :
cellular automata; clocks; logic devices; microprocessor chips; molecular electronics; quantum computing; semiconductor quantum dots; timing; QCA; QCA cell electrostatic interaction; QCA device clocking; QCA wires; binary information representation; clocking wires; data flow direction; logic devices; microprocessors; molecular computing; nanostructure charge configuration; quantum-dot cellular automata; timing; Circuits; Clocks; Computer architecture; Logic devices; Molecular computing; Nanostructures; Quantum cellular automata; Quantum computing; Quantum dots; Wires;
Conference_Titel :
Simulation of Semiconductor Processes and Devices, 2003. SISPAD 2003. International Conference on
Conference_Location :
Boston, MA, USA
Print_ISBN :
0-7803-7826-1
DOI :
10.1109/SISPAD.2003.1233626
