Road markings play a key role of traffic engineering and perform crucial functions such as directing, warning, and regulating traffic. They provide vital road information through their reflective properties and ensure safety by preventing skidding. Numerous studies have shown that well-maintained road markings significantly reduce traffic accidents. However, achieving both high reflectivity and skid resistance in road markings presents a challenge due to the conflict between glass beads and anti-skid aggregates that enhance reflectivity and skid resistance, respectively. Therefore, very few research findings addressed this area. The objective of this study is to develop dual-performance thermoplastic road markings that offer superior reflectivity and skid resistance simultaneously. Through extensive material proportion experiments, two types of dual-performance marking materials, Types A and B, were identified. These markings were applied on urban roads and subjected to 12 months data collection along with the conventional type II thermoplastic marking. The coefficient of retroreflected luminance (RL), luminance coefficient under diffuse illumination (Qd), and skid resistance (BPN) were assessed. The results indicate that Type A, characterized by an equal mix of materials applied externally, maintained adequate skid resistance (BPN ≥ 50) and exhibited remarkable reflectivity (RL ≥ 300 mcd/m²/lx) after serving 1 year. Type B, which involved the sequential application of glass beads and anti-skid aggregates, demonstrated great reflectivity (RL ≥ 200 mcd/m²/lx) and outstanding skid resistance (BPN ≥ 55) which is even better than type II markings. Based on a comprehensive review of international standards and experimental data, threshold values for construction acceptance and maintenance were also proposed in this research. Additionally, experimental factor designs on the drop-on materials were conducted. The findings provide valuable information for future road markings selection. Performance indicators were established to classify road marking performance levels, assessing service performance according to different usage scenarios. The research revealed that dual-performance Type A and Type B markings offer superior service performance compared to type II markings under various environment conditions. Through cost-effectiveness analysis, dual-performance markings showcased outstanding reflectivity in area with insufficient street lights, such as country roads, even their unit costs are higher than type II markings. It indicates that dual-performance markings are a viable option for widespread application, aiming to enhance the service level of road markings and ultimately improve road traffic safety. The proposed materials and application methods present a practical approach for maintaining markings’ high performances under diverse conditions.