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This paper presents a structural interpretation of hydrogen formation within the framework of a tension-based model of spacetime. Rather than treating hydrogen as an emergent product of particle interactions alone, the model considers it as a natural result of localized stability within a continuous medium capable of supporting tension and structural organization. Within this framework, bound structures arise when internal coherence is sufficient to balance effective tension loading. Hydrogen represents the simplest stable configuration under these conditions, serving as a foundational building block for more complex structures. The formation process is therefore interpreted not as an isolated event, but as a recurring outcome of stability conditions in a structured medium. The paper explores the relationship between energy, structure, and scale, emphasizing the role of coherence and spatial organization in determining stability. This approach provides a unified perspective in which particle formation, atomic structure, and larger-scale organization can be understood within the same conceptual framework.