Topological analysis in R(p,q)-anisotropic sector and nuclear space on R(p,q)-quantum deformed algebra

Abstract

The purpose of this article is to develop and analyze R(p,q)-topological analysis of the classical nuclear space within the general framework of R(p,q)-calculus. We begin by introducing the R(p,q)-Gamma functions, establishing their main properties and their connection with the deformed factorials. We develop a rigorous analytic and functional-analytic framework for holomorphic functions governed by a general R(p,q)-deformation, where R(u,v) is a meromorphic kernel satisfying 0<q<p≤ 1, R(1,1)=0, and R(pn,qn)>0. A Stirling-type asymptotic expansion is established for the R(p,q)-deformed Gamma function ΓR(p,q), yielding precise exponential quadratic growth estimates driven by the asymptotics of the deformed factorial R!(pn,qn) (λn2). These asymptotics induce sharp coefficient bounds and Cauchy-type inequalities for R(p,q)-entire functions. Based on these estimates, we introduce R(p,q)-weighted Banach and Fréchet spaces of holomorphic functions, together with deformation dependent pseudo-norms and valuation maps. Within this setting, we define R(p,q)-discs and anisotropic sectors adapted to the deformation geometry and prove R(p,q)-analogues of the Cauchy-Hadamard theorem, the Borel-Carathéodory inequality and Phragmén-Lindelöf type growth principles. These results contribute to the broader program of constructing a consistent functional calculus in R(p,q)-quantum algebras, with potential applications to deformed fractional differential equations, operator theory, spectral problems, and non commutative models arising in mathematical physics.