This document introduces The Imprint Hypothesis, a conceptual framework in quantum physics that proposes a reinterpretation of wave–particle duality. The framework suggests that particles are the primary quantized manifestations of excitations in pre-existing quantum fields, while waves arise as secondary imprint patterns generated through particle–field interactions and measurement contexts. Within this view, quantum fields act as the persistent substrate of physical reality. When a field is activated, it produces a quantized excitation that appears as a particle (such as a photon, electron, or proton). As these particles interact with surrounding fields and experimental apparatus, they generate interference patterns or “wave imprints.” Measurement then collapses these imprints, fixing observable outcomes while preserving the underlying particle-based ontology. The framework outlines a causal sequence: field excitation → particle emergence → field interaction → wave imprint → measurement outcome. By treating waves as contextual imprints rather than independent entities, the hypothesis offers a simplified conceptual interpretation that aims to reduce paradoxes associated with wave–particle duality. Potential areas of application include quantum computing, quantum sensing, and energy-transfer processes in systems such as semiconductor electronics and nuclear fusion, where tunneling and interference phenomena play a critical role. This handout summarizes the core ideas of the Imprint Hypothesis and serves as an introductory conceptual reference for researchers interested in alternative interpretations of quantum behavior.