Terahertz Wave Propagation Characteristics on Rough Surfaces Based on Full-Wave Simulations

Terahertz (THz) communications are considered as a critical technology for the future wireless communication. The THz band (0.1-10 THz) offers ultra-wide bandwidths and promises to satisfy the need for ultra-high-speed wireless communication. Although propagation characterization is necessary for the THz system design and validation, the response mechanism between the surface roughness and the THz wave is rarely studied. According to the Rayleigh Criterion, most surfaces in a physical environment may be considered to be rough. Scattering on rough surfaces will play a significant role in the THz propagation. Due to the difficulty of practical measurements at the THz band, we use a full-wave simulation method to study the propagation characteristics of scattering on rough surfaces. First, the Monte Carlo method is used to model rough surfaces with different root-mean-squared heights delta and correlation lengths l. Then, with full-wave simulations, frequency dependency, incident angle dependency, material dependency, and surface size dependency are discussed. By changing the roughness of surfaces, scattering on different rough surfaces at 300 GHz are simulated. Based on a large number of simulation results, we investigate the effect of delta and l on scattering on rough surfaces. Afterward, the cross-polarization discrimination of each case is analyzed and counted to evaluate the depolarization effect. This study shows that scattering can become a prominent propagation mechanism with the growth of roughness. Besides, the depolarization effect becomes much more severe for a rougher surface. Studying THz propagation characteristics on rough surfaces is critical to accurate THz channel modeling, which further supports the design and deployment of THz communication systems.

Automated summary

Terahertz (THz) communications are critical for future wireless communication. This study investigates the scattering propagation characteristics on rough surfaces using a full-wave simulation method. The results show that scattering becomes a significant propagation mechanism with increased roughness, and the depolarization effect is more severe for rougher surfaces. The findings are important for accurate THz channel modeling and the design of THz communication systems.