Paper DCQ1 constructed a phase-encoded embedding of the six-bit configuration space H6 = ±16 into the complex Grassmannian Gr (3, 6), together with metric compatibility, a finite phasesector embedding H6 −→ μ34 ⊂ U (1) 3, and two distinct carrier layers: the 20-dimensional Pluecker/Fock carrier Λ3 (C6), and the separate 24-dimensional pure Bose–Fermi readout carrier RBF = Sym3 (C4) ⊕ Λ3 (C4). The present paper develops the next geometric layer of the DCQ programme. First, the continuous completion of the three bit-pair phase blocks gives a six-dimensional phase-orbit submanifold N ≃ (CP1) 3 ⊂ Gr (3, 6), containing the 64 embedded discrete code states as a finite μ34-labelled subset. Second, the determinant Berry line bundle restricts to N with curvature class Ω2πN = (1, 1, 1) ∈ H2 ( (CP1) 3; Z), so each CP1 factor carries one unit of Berry–Chern flux. Third, a diagonal U (1) Marsden–Weinstein reduction of N gives an effective four-dimensional symplectic quotientCδ = μ−1 diag (c) /U (1) diag, dimR Cδ = 4. Finally, the paper formulates an adapted Morse-theoretic structure in which the 64 discrete states are treated as preferred minima of a smooth potential on N. The associated Picard–Lefschetz discussion is presented as a formal complexified thimble ansatz, not as a complete analytic construction of complex integration cycles. The result is a pre-dynamical geometric framework linking finite phase data, Berry–Chern topology, symplectic reduction, and semiclassical expansion.
ZHAI Xingyun (Sat,) studied this question.