Photothermal Optimization of Quantum Dot Converters for High‐Power Solid‐State Light Sources

Abstract Quantum dots (QDs) exhibit remarkable photoelectric performance. However, the conversion efficiency and thermal performance of QD converters so far is not satisfactory for high‐power solid‐state light (SSL) applications owing to the serious reabsorption loss of QDs and the poor thermal diffusion of polymer materials. Here, an efficient QD converter based on an anodic aluminum membrane (AAM), with high light enhancement and thermal diffusion, is introduced for high‐power SSL applications. Nanoporous AAMs are utilized as templates for confining the QD deposition into the nanowire (NW) shape by incorporating inkjet printing and vacuum‐deposition methods, forming vertical QD NW arrays. Compared with conventional converters, QD‐AAM yields nearly twofold photoluminescence intensity. Three‐dimensional finite‐difference (FDTD) simulations attribute the fluorescence‐enhancement mechanism to the enhancement of QD conversions and boosting of the waveguide effect in QD‐AAM. Furthermore, QD‐AAM exhibits excellent thermal diffusion performance under high‐power excitation, owing to the inner heat conduction path in the AAM framework. This study provides a practical and efficient strategy to comprehensively enhance the optical and thermal performance of QD converters for high‐power SSL applications.