Scholars@Duke publication: Proof-of-Concept Vacuum Microelectronic NOR Gate Fabricated Using Microelectromechanical Systems and Carbon Nanotube Field Emitters.

Proof-of-Concept Vacuum Microelectronic NOR Gate Fabricated Using Microelectromechanical Systems and Carbon Nanotube Field Emitters.

Publication , Journal Article

von Windheim, T; Gilchrist, KH; Parker, CB; Hall, S; Carlson, JB; Stokes, D; Baldasaro, NG; Hess, CT; Scheick, L; Rax, B; Stoner, B; Glass, JT ...

Published in: Micromachines

April 2023

Published version (DOI)

This paper demonstrates a fully integrated vacuum microelectronic NOR logic gate fabricated using microfabricated polysilicon panels oriented perpendicular to the device substrate with integrated carbon nanotube (CNT) field emission cathodes. The vacuum microelectronic NOR logic gate consists of two parallel vacuum tetrodes fabricated using the polysilicon Multi-User MEMS Processes (polyMUMPs). Each tetrode of the vacuum microelectronic NOR gate demonstrated transistor-like performance but with a low transconductance of 7.6 × 10^-9 S as current saturation was not achieved due to a coupling effect between the anode voltage and cathode current. With both tetrodes working in parallel, the NOR logic capabilities were demonstrated. However, the device exhibited asymmetric performance due to differences in the CNT emitter performance in each tetrode. Because vacuum microelectronic devices are attractive for use in high radiation environments, to test the radiation survivability of this device platform, we demonstrated the function of a simplified diode device structure during exposure to gamma radiation at a rate of 45.6 rad(Si)/second. These devices represent a proof-of-concept for a platform that can be used to build intricate vacuum microelectronic logic devices for use in high-radiation environments.

Duke Scholars

Author Jason Amsden Electrical and Computer Engineering

Author Jeffrey Glass Electrical and Computer Engineering

Author Charles Parker

Author Brian R. Stoner Electrical and Computer Engineering

Published In

Micromachines

DOI

10.3390/mi14050973

EISSN

2072-666X

ISSN

2072-666X

Publication Date

April 2023

Volume

Issue

Start / End Page

973

Related Subject Headings

4018 Nanotechnology
1007 Nanotechnology

Citation

APA

Chicago

ICMJE

MLA

NLM

von Windheim, T., Gilchrist, K. H., Parker, C. B., Hall, S., Carlson, J. B., Stokes, D., … Amsden, J. J. (2023). Proof-of-Concept Vacuum Microelectronic NOR Gate Fabricated Using Microelectromechanical Systems and Carbon Nanotube Field Emitters. Micromachines, 14(5), 973. https://doi.org/10.3390/mi14050973

Windheim, Tasso von, Kristin H. Gilchrist, Charles B. Parker, Stephen Hall, James B. Carlson, David Stokes, Nicholas G. Baldasaro, et al. “Proof-of-Concept Vacuum Microelectronic NOR Gate Fabricated Using Microelectromechanical Systems and Carbon Nanotube Field Emitters.” Micromachines 14, no. 5 (April 2023): 973. https://doi.org/10.3390/mi14050973.

von Windheim T, Gilchrist KH, Parker CB, Hall S, Carlson JB, Stokes D, et al. Proof-of-Concept Vacuum Microelectronic NOR Gate Fabricated Using Microelectromechanical Systems and Carbon Nanotube Field Emitters. Micromachines. 2023 Apr;14(5):973.

von Windheim, Tasso, et al. “Proof-of-Concept Vacuum Microelectronic NOR Gate Fabricated Using Microelectromechanical Systems and Carbon Nanotube Field Emitters.” Micromachines, vol. 14, no. 5, Apr. 2023, p. 973. Epmc, doi:10.3390/mi14050973.

von Windheim T, Gilchrist KH, Parker CB, Hall S, Carlson JB, Stokes D, Baldasaro NG, Hess CT, Scheick L, Rax B, Stoner B, Glass JT, Amsden JJ. Proof-of-Concept Vacuum Microelectronic NOR Gate Fabricated Using Microelectromechanical Systems and Carbon Nanotube Field Emitters. Micromachines. 2023 Apr;14(5):973.

Published In

Micromachines

DOI

10.3390/mi14050973

EISSN

2072-666X

ISSN

2072-666X

Publication Date

April 2023

Volume

Issue

Start / End Page

973

Related Subject Headings

4018 Nanotechnology
1007 Nanotechnology