Title :
Modeling Operational Modes of a Bipolar Vacuum Microelectronic Device
Author :
Madison, Andrew C. ; Parker, Charles B. ; Glass, Jeffrey T. ; Stoner, Brian R.
Author_Institution :
Dept. of Electr. & Comput. Eng., Duke Univ., Durham, NC, USA
Abstract :
Vacuum microelectronic devices (VMDs) designed for bipolar charge operation hold great promise for applications in radiation-intensive and high-temperature environments. This novel class of devices was first realized in a microelectromechanical platform leveraging integrated carbon nanotube field emitters and an addressable pentode structure for controlling electron-impact dynamics in Ar ambients. That proof of concept demands the development of basic numerical models to aid device optimization. We address this need in the form of a two-fluid model of carrier transport dynamics in a bipolar VMD (BVMD). The fluid model captures the behavior of operational modes demonstrated in previously reported devices. Moreover, this approach promises insight into potentially unforeseen pressure and frequency dependences of the BVMD platform.
Keywords :
bipolar integrated circuits; carbon nanotubes; carrier mobility; field emission; micromechanical devices; nanotube devices; vacuum microelectronics; Ar; BVMD platform; addressable pentode structure; bipolar VMD; bipolar charge operation; bipolar vacuum microelectronic device; carrier transport dynamics; device optimization; electron impact dynamics control; frequency dependences; high-temperature environments; integrated carbon nanotube held emitters; microelectromechanical platform; operational modes modeling; potentially unforeseen pressure; radiation-intensive environments; two-fluid model; Anodes; Carbon nanotubes; Computational modeling; Glass; Logic gates; Mathematical model; Microelectronics; Collisional plasma; finite-element methods (FEMs); fluid modeling; microelectromechanical devices;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2012.2208445
