Steel strips, renowned for their exceptional strength, durability, and impact resistance, are ubiquitous in various manufacturing sectors, notably aerospace, shipbuilding, and automotive industries. However, surface defects on these strips are inevitable due to various factors, including processing and environmental conditions. As a result, the efficient detection of these defects is paramount. This study introduces SFC-YOLOv8, a novel method for detecting surface defects on steel strips that leverages an improved YOLOv8 framework in the spatial-frequency domain. Initially, by exploiting the distinct high-frequency features of defect images, we extract mixed spatial-frequency domain features before applying YOLOv8, enhancing its sensitivity to low-contrast defects. Furthermore, we incorporate a global-local information-enhanced attention module into YOLOv8’s neck, which integrates high-frequency, low-frequency, and local perceptual information to capture defect features more effectively, boosting the model’s capability to detect minute and subtle defects. Additionally, we propose a frequency domain feature adaptive module that adaptively adjusts the soft threshold based on image frequency domain information, filtering out background noise while preserving the underlying semantic information of the image, thereby enhancing defect detection precision under varying lighting conditions. Comparative evaluations with conventional detection methods reveal that SFC-YOLOv8 achieves a mean average precision of 85.6%, a detection speed of 203 frames per second, and a compact model parameter of 4.36 MB, showcasing its superior overall performance. Ablation studies further confirm that SFC-YOLOv8 outperforms traditional YOLOv8 by enhancing detection precision by 6.6%.