Near-perfect light-capture materials with high environmental stability

Cross-wavelength near-perfect light capture technology is crucial in various fields, including spectroscopy, energy conversion, and electromagnetic control. Nevertheless, the primary challenge in broadband absorption is effectively coordinating the intrinsic response behavior of various electromagnetic waves across the nanometer-centimeter scale when interacting with matter. By adopting a multi-scale structural design strategy, the carbon-zirconium heterointerface is integrated into the macroscopic periodic unit cell (PUC) to develop an ultra-wideband light capture material. The optical coupling effect, strengthened by electronic transitions, molecular motion, and spatial scattering effects, endows ZC-PUC with exceptional light-capture performance ranging from ultraviolet to microwave frequencies. Specifically, the ZC-PUC absorber possesses a near-perfect absorption rate of 95.7% across the ultraviolet-visible-infrared spectrum (190–2500 nm), and an effective absorption coverage of 99.99% in the microwave and terahertz bands (1997.9 GHz). More importantly, the as-prepared material maintains the morphology structure and physical phase even when exposed to an alkaline or acidic environment for 365 days and simultaneously possesses stable light capture properties. The easily scalable approach retains excellent structural stability and ultra-wideband light trapping capability under extreme conditions, offering a versatile platform for the development of next-generation devices.