The W-Operator: A Volterra Fractional Time Operator with Sharp Bernstein Threshold and Regularized Memory

Abstract

We introduce a new two-parameter fractional time operator with Volterra structure, denoted by WDtα,β, defined through the Laplace symbol \[ Φα,β(s) = sα(1+(1-α)sα-1)β, 0<α<1, \ β0. \] The operator preserves the Caputo-type high-frequency behavior while allowing a controlled modification of the low-frequency regime via β. We develop an explicit symbolic/Volterra theory: Prabhakar-type kernels, a left-inverse Volterra integral, and a fractional fundamental theorem of calculus. A central contribution is a sharp clarification of the Bernstein structure of the symbol. We show that the natural factorization Φα,β(s)=sαhα(s)β does not fit the classical Bernstein product mechanism for any β>0. Nevertheless, by a direct complete-monotonicity argument on Φ'α,β, we prove the exact Bernstein threshold \[ Φα,β∈BF 0β1. \] where BF denotes the class of Bernstein functions For β>1, the Bernstein property fails by a low-frequency asymptotic convexity obstruction. This shows that the Bernstein nature of the natural range 0β1 is genuine but is not produced by the standard product mechanism. We then establish well-posedness of abstract W-fractional Cauchy problems with sectorial generators by resolvent estimates and Laplace inversion, yielding a W-resolvent family with temporal regularity and smoothing properties. As an illustration, we apply the theory to a W-fractional diffusion model and discuss the effect of β on the relaxation of spectral modes.