Abstract
Metasurfaces are an attractive technology to develop electronically-controlled beam steering devices of THz waves. However, the dynamic steering of co-polarized transmitted waves at a fixed frequency has not been demonstrated yet using this scheme. The performance of this configuration is usually limited by the low phase shifts achievable from thin-film reconfigurable meta-atoms, necessitating the exploration of novel methods. Here, we propose an alternative approach to address this challenge by designing a tunable metasurface utilizing a phase modulation range of only 116[Formula: see text]. Our design employs a meta-atom array incorporating VO[Formula: see text] patches within C-shaped split ring resonators (CSRRs). The metal-to-insulator transition of VO[Formula: see text] enables a continuously tunable phase shift with a reduced amplitude modulation, resulting in a dynamic control over the direction of co-polarized transmitted beams at 0.75 THz in the angular range spanning from -56[Formula: see text] to +56[Formula: see text]. Furthermore, we enhance the device performance by co-optimizing the distribution of phase and amplitude of the gradient profile, leading to an increase in transmission efficiency. This approach can be extended to other regions of the electromagnetic spectrum, accessing applications that require tunable beam steering operation such as imaging, LIDAR, and 6G telecommunications that cannot achieve a 360[Formula: see text] phase modulation range.