Abstract This paper presents a programmable hybrid copper–graphene metasurface antenna for simultaneous steerable beam generation in the terahertz band, targeting wide‑angle, low‑voltage multi‑beam operation for emerging 6G wireless systems. The metasurface consists of a 20 × 20 array of E‑shaped unit cells designed to operate at 2. 35 THz, with overall dimensions of 800 × 800 × 10 μm³. Each unit cell integrates an E‑shaped copper resonator with tunable graphene arms on a quartz substrate backed by a polysilicon ground plane and a thin HfO 2 gate dielectric, enabling low‑voltage electronic control. The design process begins with parametric optimization of the hybrid unit-cell geometry to maximize phase tunability at 2. 35 THz, followed by selection of an 8 nm HfO 2 gate dielectric to achieve practical low-voltage operation, and concludes with array-level phase distribution synthesis for beam steering and multi-beam generation. Comprehensive parametric study is conducted on the effect of graphene chemical potential (\: {\: }₂), relaxation time (\: \: ), and temperature (\: T) on material response characteristics for phase tuning perforFmance. At \: \: =3\: ps\: and \: T=300\: K, variation of \: {\: }₂ from 0. 22 eV to 1. 0 eV yields reflection magnitude ranging from − 10 dB to − 0. 1 dB with 355° phase coverage. The metasurface supports beam steering over elevation angles up to \: \: 68^o with full \: 360^\: azimuthal coverage, achieving a maximum gain of 17. 4 dB and maintaining acceptable sidelobe levels and beamwidth across the steering range. In addition, simultaneous dual, triple, and quadruple beams radiation patterns are realized using a superposition‑based phase synthesis, enabling independently steerable directive beams without aperture partitioning. Compared with previously reported terahertz graphene metasurfaces operating at lower frequencies with narrower steering ranges (typically ±45–60°) and single/dual-beam capabilities, the proposed design offers clear advantages in steering range, multi-beam generation (up to four beams), and biasing practicality (0. 2–4. 3 V operation), making it well suited as a reconfigurable intelligent surface for 6G terahertz wireless communication and sensing.
Elhenawy et al. (Wed,) studied this question.