Transfinite Operator Fixed Points on Hilbert Spaces: An Alpay Algebra Approach

Abstract

This work develops a functional-analytic framework based on the transfinite iteration of a self-adjoint operator. Beginning with a densely defined self-adjoint operator A on a Hilbert space H, a spectral-transform functor is applied iteratively. This process generates a transfinite sequence of operators, \α(A)\α<, by progressively enlarging the ambient Hilbert space at each ordinal stage. Under suitable continuity and monotonicity conditions on , it is established via transfinite induction that the sequence converges, stabilizing at a minimal ordinal where +1(A) = (A). The resultant limit operator, A∞ = ∞(A), is a self-adjoint fixed point of the transformation, satisfying (A∞) = A∞. Its spectrum is characterized by the relation σ(A∞)=n<∞f\,n(σ(A)), where f is the spectral map induced by . For canonical transformations, such as (A)=A2 or the semigroup action t(A)=etA, the limit operator A∞ is identified as the orthogonal projection onto the iteratively invariant eigenspaces of the initial operator A. Principal contributions include a transfinite spectral-mapping theorem, a proof of the uniqueness of A∞ up to unitary equivalence, and a reinterpretation of the discrete iteration as an evolution semigroup on an L2-type function space. The framework is demonstrated to subsume and generalize classical asymptotic-projection results. This study is partly motivated by the algebraic structures introduced by F. Alpay (arXiv:2505.15344). An appendix outlines a hierarchy of open problems in operator theory whose complexity is indexed by the iterative stage.