Master Lovas-Andai and Equivalent Formulas Verifying the 833 Two-Qubit Hilbert-Schmidt Separability Probability and Companion Rational-Valued Conjectures

Abstract

We begin by investigating relationships between two forms of Hilbert-Schmidt two-re[al]bit and two-qubit "separability functions"--those recently advanced by Lovas and Andai (J. Phys. A 50 [2017] 295303), and those earlier presented by Slater (J. Phys. A 40 [2007] 14279). In the Lovas-Andai framework, the independent variable ∈ [0,1] is the ratio σ(V) of the singular values of the 2 × 2 matrix V=D21/2 D1-1/2 formed from the two 2 × 2 diagonal blocks (D1, D2) of a 4 × 4 density matrix D. In the Slater setting, the independent variable μ is the diagonal-entry ratio 11 4422 33--with, of central importance, μ= or μ=1 when both D1 and D2 are themselves diagonal. Lovas and Andai established that their two-rebit "separability function" 1 ( ) (≈ ) yields the previously conjectured Hilbert-Schmidt separability probability of 2964. We are able, in the Slater framework (using cylindrical algebraic decompositions [CAD] to enforce positivity constraints), to reproduce this result. Further, we newly find its two-qubit (yielding 833), two-quater[nionic]-bit (yielding 26323) and "two-octo[nionic]-bit" (yielding 444824091349) counterparts. Then, we find a Lovas-Andai "master formula", d()= d (d+1)3 \,3F2(-d2,d2,d;d2+1,3d2+1; 2) (d2+1)2 encompassing both even and odd values of d. C. Koutschan, then, using his HolonomicFunctions program, develops an order-4 recurrence satisfied by the predictions of the several formulas, establishing their equivalence.