A Pure Logical Proof of the Zhu-Liang Topological Space Recursive Element Theorem

Within the axiomatic system of recursive elements, using point-set topology, algebraic topology, and category theory, this paper presents a pure logical proof that a topological space \ ( (X, ) \) (with special emphasis on compact Hausdorff spaces and CW complexes) is a fundamental recursive element of the mathematical universe. We first define the four axioms that a recursive element must satisfy: Existence (A1), Encoding Invariance (A2), Metabolic Conservation (A3), and Generativity (A4). Subsequently, we employ point-set topology and category theory to prove existence and generativity, model theory/homotopy type theory to prove encoding invariance, and algebraic topology to prove metabolic conservation. Combining these four parts yields the Zhu-Liang Topological Space Recursive Element Theorem, and we further prove at the meta-level the self-consistency of the recursively nested structure. The theorem reveals that topological spaces are not only central to the concept of continuity in modern mathematics but also core recursive elements that generate algebraic topology, differential geometry, mathematical physics, and other structures; their truth originates from the recursive self-consistency requirement of the formal system itself.