In this work we investigate the deep geometric nature of Kähler manifolds and propose a solution to the fundamental metric problem in Synthetic Differential Geometry (SDG). We show that the three defining conditions of Kählerness — Hermiticity, the existence of a Kähler form, and its closedness — are not independent axioms but are direct consequences of the fact that space is "woven" at the micro-level from infiniums ℑ = △₁ₓ₁ (right isosceles triangles with legs 1 and hypotenuse √2). Within the framework of △-ontology, the infinium serves as the terminal object of the energetic topos 𝒯 = Sh(Site(△₁ₓ₁)). The condition dω = 0 turns out to be the continuous expression of discrete self-similarity Φ ∘ Ψ = id, while Hermiticity is the symmetry of two equal legs. We then show how the infinium resolves the conflict between infinitesimal closeness (∼) and finite distance (#) in SDG, replacing the modulus |x| with a smooth quadratic form and defining distance via the length of the hypotenuse. In this way the metric ceases to be an external structure and emerges from the geometry of the infinium itself. Our theory asserts that every Kähler manifold is necessarily generated by △-mosaics, and the infinium forces both the Kähler condition and the resolution of the metric problem.
Alexey (KAMAZ) Petrov (Mon,) studied this question.