Accession Number : ADA626556


Title :   Energy-Filtered Tunnel Transistor: A New Device Concept Toward Extremely-Low Energy Consumption Electronics


Descriptive Note : Final technical rept. 1 Apr 2012-30 Sep 2015


Corporate Author : TEXAS UNIV AT ARLINGTON DEPT OF MATERIALS SCIENCE AND ENGINEERING


Personal Author(s) : Koh, Seong J


Full Text : https://apps.dtic.mil/dtic/tr/fulltext/u2/a626556.pdf


Report Date : 17 Dec 2015


Pagination or Media Count : 41


Abstract : This project has investigated fundamental physics of electron energy filtering occurring at room temperature as well as its applications to practical devices such as room-temperature single-electron transistors and ultralow energy consumption transistors. We have experimentally demonstrated, for the first time, that a quantum well energy level can filter out energetic electrons that are present at the Fermi-Dirac distribution tail, thereby effectively suppress the Fenni-Dirac electron thermal excitations, producing energy-filtered cold electrons at room temperature. The effective temperature of the energy-filtered cold electrons was 45 Kelvin at room temperature. A comprehensive microscopic model has been developed to describe the underlying mechanisms of the energy filtering and numerical calculations are in excellent agreement with experimental findings. The energy filtering has been applied to single-electron transport and clear Coulomb staircases and Coulomb oscillations have been demonstrated at room temperature. A new architecture of energy-filtered cold electron transistors has been designed and fabricated using optimized materials/processes.


Descriptors :   *ELECTRONS , *ENERGY CONSUMPTION , *LOW ENERGY , *TRANSISTORS , AGREEMENTS , COMPUTATIONS , DISTRIBUTION , ENERGY , ENERGY LEVELS , FILTERS , MATERIALS , MICROSCOPY , MODELS , NUMERICAL ANALYSIS , OPTIMIZATION , OSCILLATION , QUANTUM DOTS , QUANTUM THEORY , QUANTUM WELLS , TEMPERATURE , TRANSPORT


Subject Categories : Electrical and Electronic Equipment
      Electric Power Production and Distribution
      Nuclear Physics & Elementary Particle Physics


Distribution Statement : APPROVED FOR PUBLIC RELEASE