1. Introduction

Recent years have witnessed the fast evolution of the display technology towards wide color gamut, high dynamics, and high-definition, which also put forward new demands for light-emitting diodes (LEDs) integration technologies and luminescent materials [1]–[2]. Among them, micro/mini-LED display technology has shown strong competitive advantages with its high brightness, ultra-fast response, wide color gamut, and low power consumption [3]–[4]. However, integrating multi-color micro/mini-LED chips in large display panel face the difficulties in mass transfers of RGB color chips, low assembly yield, high manufacturing cost, and complicated driving circuits [5]–[6]. Therefore, the use of monochromatic blue or ultraviolet micro/mini-LEDs plus multi-color luminescent light-down conversion materials has become a viable technical solution because of the economic benefit and simpler processing [7]–[8]. Colloidal quantum dots (QDs) are ideal fluorescent materials with their broad color tunability, high photoluminescence quantum yield (PLQY), and narrow-band emission to fulfill the purpose [9]–[11]. Especially, unlike conventional micro-sized phosphors, QDs possess a size of less than 100 nm and a surface that can be easily tailored with organic ligands to realize mono-dispersion in various polymer matrices for compatibility with micro/nano manufacturing process. [12]–[13] These promising characteristics make the QDs remarkable light-conversion material that meets the high demands of ultra-wide color gamut in next-generation display standards [15]–[16].