Quantum-Adaptive KS(φ): A Parameterized Three-Qubit Gate Family Embedding Toffoli with Measurement-Free Phase Kickback and Intrinsic Error Non-Amplification

Abstract

We introduce Quantum-Adaptive KS(φ) (K = kickback, S = sandwich), a parameterized three-qubit gate family that structurally embeds the Toffoli (CCX) gate within two additional components: (1)a palindromic Hadamard sandwich on the first control qubit q0 that conjugates Z-type errors to X-type in the CCX frame, providing simultaneous sensitivity to both error types without ancilla overhead; and (2)a controlled-phase (CP) gate whose quantum phase kickback propagates post-CCX target-state information into the control-qubit phase without measurement. The term Quantum- Adaptive refers to amplitude steering conditioned by the compile-time parameter φ via a Quantum Neural Cellular Automaton (QNCA) majority-inspired bias rule; the gate does not self-modify at runtime. Two QA-KS(π) gates chained on a shared control qubit q0 produce outputs completely orthogonal to two sequential CCX gates on q0=1 inputs (output fidelity F=0.000), while agreeing exactly on q0=0 inputs (F=1.000). This subspace-dependent divergence is the direct computational signature of coherent phase retention across gate boundaries -- impossible for CCX-only circuits. On the q1 = 0 subspace the gate acts deterministically (up to a relative phase), providing intrinsic error non-amplification. On the q1 = 1 subspace it produces four-component entangled superpositions, making it a strictly distinct quantum-native primitive from CCX. We present the complete 8 × 8 unitary matrix, confirmed exact to ||UU-I||∞ < 10-15, and define two canonical variants: QA-KSπ/2 (φ= π/2, S gate) and QA-KSπ (φ= π, Z gate). Qiskit depolarizing-noise simulation demonstrates near-unit fidelity at p ≤ 10-2 with an honest depth cost at higher error rates. The gate preserves the three-qubit footprint of CCX with no qubit overhead.