Indefinite Causal Order Skip Logic with Coherently Conditioned Subroutines and Application to Grover Search

Indefinite causal order (ICO) allows quantum circuits to coherently superpose the sequence of operations, creating computational possibilities beyond fixed gate ordering. This work introduces the Quantum Skip Gate (QSG), a new unitary circuit primitive that extends ICO to coherently control whether an expensive quantum subroutine is executed, without mid-circuit measurement or loss of coherence. Unlike conventional ICO constructions that superpose gate sequences, the QSG superposes the presence or absence of operations themselves, enabling conditional quantum logic in a fully unitary setting. Demonstrated experimentally in a Grover-style search on IBM quantum hardware (n = 4, k = 3), the QSG reduces costly subroutine calls by 9-25 percent, achieving a 31-61 percent improvement in success-per-oracle efficiency relative to a fixed-order baseline. Noise-model simulations confirm and strengthen these efficiency gains (up to 45 percent) when using an optimized "swap-out" design. These results demonstrate that ICO can provide practical, coherence-preserving resource management, significantly reducing runtime costs and noise accumulation in near-term quantum algorithms.