Publications: All

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  1. CNRS - Carbon Nanotube Interconnect RC Model

    2017-11-09 16:25:31 | Compact Models | Contributor(s): Jie LIANG, Aida Todri | doi:10.4231/D3SJ19T14

    A carbon nanotube interconnect compact model is developed with fundamental physics understanding and electrical modeling. Single Wall Carbon Nanotube (SWCNT) RC electrical model takes into the account the quantum resistance and capacitance, as well as electrostatic capacitance. A doped...

  2. UCSB Graphene Nanoribbon Interconnect Compact Model

    2017-05-03 21:16:20 | Compact Models | Contributor(s): Junkai Jiang, Kaustav Banerjee, Wei Cao | doi:10.4231/D3NK3663N

    As the (local) interconnect dimension scales down to sub-20 nm, the rapidly increasing metal resistance by barrier layer and surface and grain boundary scatterings, and the diminishing current carrying capacity by self-heating and Joule-heating, the metal (Cu) interconnect cannot meet the...

  3. Berkeley VCSEL Compact Model

    2015-06-02 18:58:52 | Compact Models | Contributor(s): Adair Gerke, Connie J. Chang-Hasnain | doi:10.4231/D3T43J40H

    The U.C. Berkeley Vertical Cavity Surface Emitting Laser (VCSEL) Compact Model provides a circuit simulator compatible Verilog-A model of VCSEL lasers, primarily for use in designing direct-modulation driver circuits for optical interconnects.
  4. UCSB Graphene Nanoribbon Interconnect Compact Model

    2015-04-30 14:25:13 | Compact Models | Contributor(s): Junkai Jiang, Wei Cao, Kaustav Banerjee | doi:10.4231/D34Q7QR19

    UCSB GNR interconnect model is based on a distributed RLC circuit, in which carrier mean free path, graphene doping concentration (Fermi level) and number of layers are considered. The model was originally published by UCSB NRL group.