Higher Residue Pairing for p-adic Isocrystals and the p-adic Riemann--Hilbert Correspondence

Abstract

We construct a canonical sesquilinear pairing on the relative crystalline cohomology of a smooth proper family of varieties over a complete discretely valued p-adic field. Motivated by the role of Saito's higher residue pairing in the theory of primitive forms and complex variations of Hodge structure, we develop a p-adic analogue based on the twisted relative de~Rham--Witt complex. We show that this twisted complex defines a filtered F-isocrystal whose cohomology carries a natural flat, Frobenius-compatible, and non-degenerate bilinear form. Its specialization at the uniformizer recovers the classical Grothendieck residue on the special fiber, providing a direct bridge between crystalline geometry and residue theory. Using the p-adic Riemann--Hilbert correspondence of Faltings and Liu--Zhu, we further identify the resulting pairing with the unique flat extension of this residue form to the corresponding p-adic local system. The construction is functorial in the family and compatible with base change and p-adic comparison isomorphisms. This yields a genuine p-adic analogue of Saito's higher residue pairing and supplies foundational ingredients for a prospective theory of p-adic primitive forms, p-adic TERP structures, and p-adic Frobenius manifolds.