Autonomous stabilization with programmable stabilized state

Reservoir engineering is a powerful technique to autonomously stabilize a quantum state. Traditional schemes involving multi-body states typically function for discrete entangled states. In this work, we enhance the stabilization capability to a continuous manifold of states with programmable stabilized state selection using multiple continuous tuning parameters. We experimentally achieve $84.6\%$ and $82.5\%$ stabilization fidelity for the odd and even-parity Bell states as two special points in the manifold. We also perform fast dissipative switching between these opposite parity states within $1.8\mu s$ and $0.9\mu s$ by sequentially applying different stabilization drives. Our result is a precursor for new reservoir engineering-based error correction schemes.