Simulation and Characterization of an Inverter Logic Gate by Utilizing InGaAs-Based Planar Devices

F. Aziz; S. R. Kasjoo; N. F. Zakaria; Fauzi Packeer; A. K. Singh

doi:10.58915/ijneam.v16iDECEMBER.387

Authors

F. Aziz
S. R. Kasjoo
N. F. Zakaria
Fauzi Packeer
A. K. Singh

DOI:

https://doi.org/10.58915/ijneam.v16iDECEMBER.387

Abstract

Electronic circuits known as logic gates can perform basic logical operations like inverters, AND, and OR gates. These logic gates serve as the basis for digital electronics, and they are a common component in various electronic devices, such as computers, smartphones, and other types of digital systems. This research presents an inverter logic gate made of planar devices, which have significantly simpler structures than multi-layered transistors and diodes, namely the self-switching diode (SSD) and side-gated transistor (SGT). The inverter logic gate is realized by simply connecting both SSD and SGT in parallel. The electrical characteristics and performances of the inverter logic gate are assessed based on InGaAs material using SILVACO Inc.'s ATLAS device simulator software. The simulation results show that the functionality of the proposed planar inverter is comparable to that of a conventional inverter logic gate based on the standard truth table of the device. This has demonstrated the feasibility of building logic gates using a combination of SSDs and SGTs. In addition, the planar structure of SSD and SGT allows for a relatively low-cost device fabrication process as well as offering a high-frequency operation due to low parasitic elements in the devices.

Keywords:

Inverter, self-switching diode, side-gated transistor

References

Lijun Liu, Pingping Liu, Lu Ga, & Jun Ai, Advances in Applications of Molecular Logic Gates. ACS Omega 2021, issue 6 (2021) pp. 30189−30204.

Mateos, J. & Song, A. & Vasallo, B.G. & Pardo, Diego & González, Tomás, THz operation of self-switching nano-diodes and nano-transistors. Proc SPIE. Vol 5838 (2005) pp. 145- 153.

K Y Xu et al. Effects of three-dimensional electric-field coupling on a side-gated nanotransistor. Semicond. Sci. Technol. vol 26, Number 9 (2011).

A. M. Song, M. Missous, P. Omling et al., Unidirectional electron flow in a nanometer-scale semiconductor channel: A self-switching device. Appl. Phys. Lett. vol 83, issue 9 (2003) pp. 1881–1883.

G. Farhi, E. Saracco, J. Beerens, D. Morris, S. A. Charlebois, J.-P. Raskin. Electrical characteristics and simulations of self-switching-diodes in SOI technology. Solid. State. Electron. vol 51, issue 9 (2007) pp. 1245–1249.

Kasjoo, Shahrir Rizal & Singh, Arun and Song, A., RF characterization of unipolar nanorectifiers at zero bias: RF characterization of unipolar nanorectifiers. Physica Status Solidi (A) Applications and Materials. vol 212, issue 9 (2015).

Kasjoo, Shahrir Rizal & Zailan, Zulfadli & Zakaria, Nor Farhani & Mohamad Isa, Muammar & Arshad, Mohd & Taking, Sanna, “An overview of self-switching diode rectifiers using green materials,” in AIP Conference Proceedings, (2017) pp. 020257.

Cortes-Mestizo, Irving & Briones, Edgar & Espinosa-Vega, L.I. & Mendez-Garcia, V.H.,” Semiconductor Surface State Engineering for THz Nanodevices,” in book Electromagnetic Materials and Devices, ISBN: 978-1-78985-226-4, (2020).

Kasjoo, Shahrir Rizal & Singh, Arun & Zhang, Linqing. Fabrication process of InGaAs- based nanodiode array using electron-beam lithography technique. Journal of Physics: Conference Series. vol 1535, (2020) pp. 012014.

Ng, S. M. Sze and Kwok K., “Physics of Semiconductor Devices,” 3rd ed. John Wiley & Sons, Inc. (2007) pp. 374-401.

Jin, J., “Metal-Oxide-Based Electronic Devices”, Student thesis: Phd, Department of Electrical & Electronic Engineering, The University of Manchester [Online], (2013). Available: https://research.manchester.ac.uk/en/studentTheses/metal-oxide-based- electronic-devices.

Zakaria, Nor Farhani & Kasjoo, Shahrir Rizal & Zailan, Zulfadli & Mohamad Isa, Muammar & Taking, Sanna & Md A, Mohd Khairuddin. Permittivity and temperature effects on rectification performance of self-switching diodes with different geometrical structures using two-dimensional device simulator, Solid-State Electronics, vol 138, (2017) pp.16-23.

N. F. Zakaria, S. R. Kasjoo, M. M. Isa, Z. Zailan, M. B. M. Mokhar, N. Juhari. Application of Taguchi method in optimization of structural parameters in self-switching diode to improve the rectification performance, AIP Conference Proceedings, vol 2203, (2020) pp. 020047.

Markku Åberg, Jan Saijets, Aimin Song & Mika Prunnila. Simulation and Modelling of Self-switching Devices, Physica Scripta, vol 2004, (2004) pp. 123.