Author_Institution :
Dept. of Comput. Sci., Boise State Univ., ID, USA
Abstract :
Quantum-dot cellular automata (QCA), a method for computing through energy relaxation via quantum mechanical effects, promise high speed, very low power, and extremely high density. The first steps in implementing QCA have been taken; a small device has recently been manufactured and is logical switching behavior demonstrated. This paper investigates the behaviors of some proposed QCA primitives: wires, crossings, corners, and logic gates, under two charge neutralization schemes. While these primitives work well under the originally proposed charge neutralization scheme, it is shown that with a more realistic scheme, most of the primitives can fail outright, show a preference for a undesirable logical state, or show a decrease in the energy gap between the ground state and other excited states. Redesigned primitives are presented which may perform as well, or better, under either neutralization scheme
Keywords :
cellular automata; quantum computing; quantum dots; quantum gates; asymmetric charge neutralization; corner; crossing; energy relaxation; logic gate; logical switching device; primitive design; quantum computing; quantum dot cellular automata; symmetric charge neutralization; wire; Electrons; Land surface temperature; Logic gates; Manufacturing; Quantum cellular automata; Quantum computing; Quantum dots; Quantum mechanics; Stationary state; Wires;
