3D Reconfigurable Vectorial Holography via a Dual‐Layer Hybrid Metasurface Device

Metasurface‐based vectorial holography manifests itself as an advanced platform for large‐capacity information storage, holographic display, and cryptography. However, a convenient and effective reconfigurable vectorial hologram generation mechanism still remains a challenge. Here, a rotation‐driven reconfigurable vectorial holography scheme is developed via a dual‐layer hybrid metasurface device, in which radiation‐type and birefringent metasurfaces are cascaded hybridly. Thus, reconfigurable and highly customizable intensity and polarization response of holograms in the 3D space is achieved. Rotatable radiation‐type metasurface (RTM) serves as an incidence‐wavefront modulator to excite the non‐rotatable birefringent metasurface (BM). The gradient descent optimization inverse design method is introduced to achieve the high‐efficiency reconstruction of the Jones vector and Jones matrix distribution on both RTM and BM. On this basis, numerical analysis and experimental verification of 3‐D reconfigurable vectorial holography are demonstrated in the microwave region. This scheme implies a new paradigm for 3‐D reconfigurable vectorial holography and can lead to advances in high‐capacity optical display, switchable meta‐devices, and cryptography. This work develops a rotation‐driven reconfigurable vectorial holography scheme via a dual‐layer hybrid metasurface device in which radiation‐type and birefringent metasurfaces are cascaded hybridly as well as the gradient descent optimization inverse design method. Numerical analysis and experimental verification of 3‐D reconfigurable vectorial holography are demonstrated in the microwave region, verifying the validity of the strategy.