Proposals for experimentally realizing (mostly) quantum-autonomous gates

The paper proposes ways to build quantum-autonomous gates—quantum operations that run without time-dependent external control—to reduce the classical control burden in quantum computing. It suggests implementations on three experimental platforms (Rydberg atoms, trapped ions, and superconducting qubits), showing how interactions or trap engineering can realize useful single- and two-qubit gates. These gates could help form largely autonomous quantum circuits with reduced classical overhead.