Projects:2020s2-7153 High-efficiency planar waveguides for terahertz waves

From Projects
Revision as of 17:27, 9 June 2021 by A1783687 (talk | contribs) (Objectives)
Jump to: navigation, search

Abstract

Terahertz integrated systems are still in its infancy in terms of its technology. However, it has shown a great number of potential uses in communication, radar, imaging and sensing. This project aims to continue the study of waveguide by examining the dispersion, cross-polarization and crosstalk, along with the characteristics of bends and crossings over the 220 to 330 GHz (WR-3 band) operating frequency range. The waveguides are substrate-less effective medium with a subwavelength arrays of hole while supporting Ex11 and Ey11 modes with low loss and low dispersion. As a step to reduce significant absorption in metals and dielectrics at terahertz frequencies, the self-supporting structures are built by using a single silicon wafer.

Introduction

With a substantially growing proportion of the world's population accessing online services, data traffic has grown significantly. Most terahertz (THz) sources, however, are inaccessible, so designing efficient THz waveguides for versatile broadband THz radiation delivery is an important step towards terahertz techniques for practical applications. The terahertz spectrum that covers the frequency range from 0.1 to 10THz is an appropriate option for the support of the high-speed wireless sight transmission line by convergence electronics and optics. When used to connect the numerous THz point devices, such as sources, filters, sensor cells and detectors, THz waveguides can be very beneficial on system integration stage.

Project team

Project students

  • Mahmoud Alshnqiti
  • Muhammad Zulhisyam Mohd Hosni
  • Muhammad Hairie Mohd Hamdan

Supervisors

  • Dr. Withawat Withayachumnankul
  • Dr. Wendy Lee
  • Weijie Gao

Objectives

The prinicple objective of this project to enhance the effective-medium-clad waveguides which is a promising candiate for terahertz integrated circuits. The project has 3 main objectives. Firstly, to improve the efficiency of the waveguides by improving the intermodal dispersion from high-order modes. Next, to decrease the standard bend footprint to enhance the compactness of the waveguides. Lastly, to propose a beam splitter in order to increase the data carrying capacity.

Background

No object

Method

Results

Conclusion

References