Title :
Computing With Nonequilibrium Ratchets
Author :
Kabir, Muhammad ; Unluer, D. ; Lijun Li ; Ghosh, Avik W. ; Stan, M.R.
Author_Institution :
Charles L. Brown Dept. of Electr. & Comput. Eng., Univ. of Virginia, Charlottesville, VA, USA
Abstract :
Electronic ratchets transduce local spatial asymmetries into directed currents in the absence of a global drain bias by rectifying temporal signals that reside far from the thermal equilibrium. We show that the absence of a drain bias can provide distinct energy advantages for computation, specifically, reducing static dissipation in a logic circuit. Since the ratchet functions as a gate voltage-controlled current source, it also potentially reduces the dynamic dissipation associated with charging/discharging capacitors. In addition, the unique charging mechanism eliminates timing-related constraints on logic inputs, in principle allowing for adiabatic charging. We calculate the ratchet currents in classical and quantum limits, and show how a sequence of ratchets can be cascaded to realize universal Boolean logic.
Keywords :
Boolean functions; active networks; capacitors; logic circuits; adiabatic charging; dynamic dissipation; electronic ratchets; global drain bias; local spatial asymmetries; logic circuit; nonequilibrium ratchets; quantum limits; static dissipation; temporal signals; thermal equilibrium; universal Boolean logic; voltage-controlled current source; Boundary conditions; Capacitors; Clocks; Electric potential; IEEE Potentials; Logic gates; Mathematical model; Current-voltage characteristics; Laplace equations; electric potential; logic gates; power dissipation; spatiotemporal phenomena;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2013.2246796
