Electronic digital logic circuitry – Threshold
Patent
1996-02-27
1997-10-14
Westin, Edward P.
Electronic digital logic circuitry
Threshold
326136, 326 93, H03K 1923, H03K 1900
Patent
active
056776373
ABSTRACT:
A memory device includes a memory node (2) to which is connected a tunnel barrier configuration such that the node exhibits first and second quantized memory states for which the level of stored charge is limited by Coulomb Blockade and a surplus or shortfall of a small number of electrons for example ten electrons or even a single electron can be used to represent quantized memory states. A series of the nodes N0-N3 that are interconnected by tunnel barriers D can be arranged as a logic device. Clock waveforms V1-V3 applied to clock lines C1 1-C1 3 selectively alter the probability of charge carriers passing through the tunnel diodes D from node to node. An output device, typically a Coulomb blockade electrometer provides an output logical signal indicative of the logical state of node N3. Arrays of separately addressable memory cells M.sub.mn are also described, that utilize gated multiple tunnel junctions (MTJs) as their barrier configurations. Side gated GaAs MTJ structures formed by selective etching and lithography are described. Also, gate structures which modulate a conductive channel with depletion regions to form multiple tunnel junctions are disclosed.
REFERENCES:
patent: Re25867 (1965-09-01), Richards
patent: 2923817 (1960-02-01), Wanlass
patent: 3209163 (1965-09-01), Wendt, Jr.
patent: 3259759 (1966-07-01), Giaever
patent: 3643237 (1972-02-01), Anacker
patent: 3882472 (1975-05-01), Smith
patent: 3986180 (1976-10-01), Cade
patent: 4103312 (1978-07-01), Chang et al.
patent: 5258625 (1993-11-01), Kamohara et al.
Microelectronika, vol. 16, No. 3, pp. 195-209, May-Jun. 1987; K. K. Likharev, "Possibility of Creating Analog and Digital Integrated Circuits Using The Discrete, One Electron Tunneling Effect".
IBM J. Res. Develop., vol. 32, No. 1, Jan. 1988, pp. 144-157; K. K. Likharev: Correlated discrete transfer of single electrons in ultrasmall tunnel junctions.
Plenum Press, New York, NY, 1992, Series B: Physics vol. 294, Chapter 9: Single Charge Tunneling; D.V. Averin and K. K. Likharev, edited by Hermann Grabert and Michel H. Devoret.
Physical Review Letters, vol. 67, No. 22, 25 Nov. 1991; T. A. Fulton, P. L. Gammel, and L. N. Dunkleberger, pp. 3148-3150: Determination of Coulomb-Blockade Resistances and Observation of the Tunneling of Single Electrons in Small-Tunnel-Junction Circuits.
C.R. Acad. Sci., Paris, t 314, Series II, pp. 883-888, 1992; P. Lafarge et al.: Direct observation of macroscopic charge quantization: a Millikan experiment in a submicron solid state device.
Electronics Letters, vol. 29, No. 4, 18 Feb. 1993, pp. 384-385, Nakazato et al.: Single-Electron Memory.
Journal of Applied Physics, vol. 72, No. 9, 1 Nov. 1992, New York, US: pp. 4399-4413, J. R. Tucker: Complementary Digital Logic Based on the "Coulomb Blockade".
Applied Physics Letters, vol. 60, No. 22, Jun. 1992, New York, US, pp. 2726-2728; J. Allam et al.: Optical second-harmonic generation in laterally asymmetric quantum dots.
Applied Physics Letters, vol. 59, No. 18, Oct. 1991, New York, US, pp. 2302-2304; C. Sirtori et al.: Observation of large second order susceptibility via intersubband transitions at lambda = 10 microns in asymmetric coupled AlInAs/GaInAs quantum wells.
Applied Physics Letters, vol. 52, No. 9, Feb. 1988, New York, US, pp. 697-699; L. Tsang et al.: Electric-field control of optical second-harmonic generation in a quantum well.
IRE Transactions On Electronic Computers, Jun. 1961, pp. 183-190; H.S. Yourke et al.: Eskaski Diode NOT-OR Logic Circuits.
Coulomb Blockade of Single-Electron Tunneling, and Coherent Oscillations in Small Tunnel Junctions; Journal of Low Temperature Physics, vol. 62, Nos. 3/4, 1986, D.V. Averin & K.K. Likharev.
Frequency-Locked Turnstile Device for Single Electrons; Physical Review Letters, vol. 64, No. 22, 28 May 1990; L.J. Geerlings et al.
Observation of the Coulomb Blockade of Tunneling in a "Single Electron Box"; pp. 55-73, Thesis by Hugues Pothier, University of Paris, 16 Sep. 1991.
Single-Electron Transistors: Electrostatic Analogs of the DC Squids; IEEE Translations on Magnetics, vol. MAG-23, No. 2, Mar. 1987; K.K. Likharev.
Possible Logic Circuits Based on the Correlated Single-Electron Tunneling in Ultrasmall Junctions; K.K. Likharev and V.K. Semenov, Department of Physics, Moscow State University, Moscow, RU, pp. 182-185, 1987 International Superconductivity Electronics Conference (ISEC '87), Aug. 28, 1987.
Ahmed Haroon
Nakazato Kazuo
White Julian D.
Hitachi , Ltd.
Roseen Richard
Westin Edward P.
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