The central theme of this work is a solution to the fundamental metric problem in synthetic differential geometry (SDG), as formulated by Anders Kock. We show that the conflict between infinitesimal closeness (∼) and finite apartness (#) is completely resolved if one adopts as the fundamental unit of space not a structureless point, but the infinium ℑ = △₁ₓ₁ (a right isosceles triangle with legs of 1 and hypotenuse √2). Replacing the singular distance function |x − y| with the length of the hypotenuse, computed via the Pythagorean theorem in a discrete △-lattice, yields a smooth metric compatible with the SDG axioms. Nilpotents acquire a geometric body through the identity (√2)² − 1² − 1² = 0. As an important corollary, we demonstrate that the key conditions of Kähler geometry — hermiticity, the Kähler form, and its closedness (dω = 0) — follow naturally from the same principles of infinium self-similarity as the solution to the metric problem. Thus, the infinium, which serves as the terminal object in the energetic topos 𝒯 = Sh(Site(△₁ₓ₁)), unifies within itself both the resolution of the ∼/# conflict and the structural foundation of Kähler manifolds, offering a new, coherent view of the fabric of reality.
Alexey (KAMAZ) Petrov (Mon,) studied this question.