Deterministic Assembly of Colloidal Quantum Dots for Multifunctional Integrated Photonics

Colloidal quantum dots (CQDs) are promising for photonic applications toward lasers, waveguides, and photodetectors. However, integration of high‐quality photonic elements into multifunctional devices is still restricted by optical losses stemming from the accumulation of defects and disorder in the solution process. Herein, a platform with a directional Laplace pressure is created for eliminating undesired pinning of liquid fronts in the solution process and boosting ordered assembly of CQDs into designable micro‐/nanostructures. The versatility and robustness of this method are demonstrated by deterministic patterning of CQDs with different components and photoluminescence spectra onto various substrates. On the basis of this platform, microring lasers with tunable emission modes, low‐loss waveguides, and their coupled structures have been reached for direct on‐chip generation and propagation of coherent light. A proof‐of‐concept demonstration of integrated circuits is also conducted by combining microcavity lasers with waveguides for encoding photonic outputs into information bits. Deterministic patterning of colloidal quantum dots into high‐quality micro‐/nanostructures is developed for the construction of multifunctional integrated photonic devices. Mode‐tunable microlasers and waveguides are coupled to direct on‐chip generation and propagation of coherent light, which permits a proof‐of‐concept demonstration of integrated photonic circuits for encoding photonic outputs into information bits.