Designing Learning Paths Using Semantic Waves

The persistent gap between theoretical understanding and practical competence─the Theory–Practice (T-P) gap─poses a well-recognized challenge in undergraduate chemical education. Recent research attributes this gap to outdated curriculum designs, inadequate teaching methods, and a lack of integration of theoretical and practical learning experiences. Various strategies, such as flipped teaching, inquiry-based learning, and project-based approaches, have been proposed to address specific aspects of the problem. Building upon prior work that framed threshold concepts as critical for integrating theory and practice in chemistry, this article proposes and demonstrates the use of semantic waves as a systematic planning heuristic. Semantic waves model the dynamic shifts across levels of conceptual complexity and real-world applications, offering educators a flexible “musical score” to orchestrate progressive learning paths that scaffold the crossing of conceptual thresholds. This approach invites a reimagining of teaching as the art of composing didactic oscillations where instructional rhythm and range are adapted to support meaningful integration. Applications across inorganic, organic, physical, and analytical chemistry are illustrated, reinforcing the generalizability of the approach. By challenging rigid curricular models and embracing more flexible, adaptive designs, semantic waves emerge as a practical and customizable tool to foster deeper learning and bridge the theory–practice gap in chemical education.