Recent progress in terahertz modulation using photonic structures based on two‐dimensional materials

Terahertz (THz) technology has attracted great attention in the past few decades for its unique applications in various fields, including spectroscopy, noninvasive detection, wireless communications, and imaging. In parallel to this, the practical, fast, and broadband modulation of THz waves is becoming indispensable. Two‐dimensional (2D) materials exhibit unusual optical and electrical properties, which has prompted tremendous interest and significant advances in THz modulation. This review provides the recent progress in 2D materials‐based THz modulators, outlining the operating principles, including all‐optical, electro‐optic, magneto‐optic, and other exotic mechanisms. We focus on the recent advances in THz modulation by the designed photonic structures, such as heterostructure, metamaterial, capacitor, optical cavity, and waveguide integration. Lastly, we discussed the challenges and opportunities for 2D materials‐based THz modulators and presented our prospects for the future development. Two‐dimensional (2D) materials‐based terahertz (THz) modulators are attracting increased attention because they play important roles in THz communication, sensing, and biomedical diagnostics. This review summarizes the recent progress of 2D materials for THz modulation with different operation principles and photonic structures. The challenges and prospects for 2D‐materials‐based THz modulators are also proposed to further push forward the development of THz modulation.