Structural color materials, as environmentally friendly dyes, have garnered significant attention from researchers. It has been observed that photonic crystal structured colors possess vivid colors that resist fading. However, their colors change with the observation angle, which limits their application in the textile field. Compared with photonic crystal structured colors, amorphous photonic crystal structured colors exhibit bright and angle-independent coloration due to their unique defective structure. The lattice points in this structure are arranged in a lower order, resulting in a short-range ordered and long-range disordered structure. When light passes through the amorphous photonic crystal structure, it is scattered uniformly in all directions, creating an isotropic photonic band gap. Consequently, a structural color that remains constant regardless of the angle is produced. This angle-independent color is highly desirable for everyday use and holds great potential for the development in the textile printing and dyeing industry. This study provides a review of the color generation principles of amorphous photonic crystal structured color, the classification of amorphous photonic crystal structures found in nature, and discusses the preparation methods of fabric featuring amorphous photonic crystal structured colors along with the latest research progress both domestically and internationally. Furthermore, it analyzes the current issues in the preparation of structural color-generating fabrics and proposes future research directions in this area. Key aspects necessary for the practical application of amorphous photonic crystal structural color-generating fabrics are also highlighted. Currently, there are two methods for preparing structural color fabrics with amorphous photonic crystals: reducing the ordered arrangement of the lattice through colloidal particle self-assembly, primarily employing techniques such as atomization deposition, spraying and screen printing, and modifying the uniformity of nanosphere sizes so as to reduce the orderedness of their self-assembly, mainly by constructing core-shell structures. Additionally, doping and redispersion methods can also alter the size uniformity of nanospheres, although their application in the textile field remains limited. These methods can serve as a reference for the future preparation of amorphous photonic crystal structured colored fabrics. In the context of the “double carbon”, achieving high-quality and environmentally-friendly development in the textile industry is an inevitable choice. Structured color possesses advantages such as bright color, high brightness, non-pollution, and fade resistance, making it suitable for application in the textile dyeing and finishing industry. It is expected to address the issues of high pollution and energy consumption associated with traditional printing and dyeing processes, so as to enable the industry to achieve sustainable development. Although amorphous photonic crystal structured color has achieved promising research results, there are still some challenges to overcome. However, with continual research, it is believed that these obstacles can be overcome, allowing for the widespread utilization of amorphous photonic crystal structured color in various related industries. [ABSTRACT FROM AUTHOR]