Robust M{\o}lmer-S{\o}renson gate for neutral atoms using rapid adiabatic Rydberg dressing.

The Rydberg blockade mechanism is now routinely considered for entangling qubits encoded in ground states of neutral atoms. Challenges towards implementing entangling gates with high fidelity include errors due to thermal motion of atoms, laser amplitude inhomogeneities, imperfect Rydberg blockade, and finite Rydberg state lifetime. We show that adiabatic rapid passage by Rydberg dressing provides a mechanism for implementing two-qubit entangling gates by accumulating phases that are robust to imperfections such as random atomic motion, laser inhomogeneities, and which can accommodate an imperfect blockade. We find that the typical error in implementing a two-qubit gate, such as the controlled phase gate, is dominated by errors in the single atom light shift, and that this can be easily corrected using adiabatic dressing interleaved with a simple spin echo sequence. This results in a two-qubit Molmer-Sorenson gate. A gate fidelity $\sim 0.995$ is achievable with modest experimental parameters and a path to higher fidelities is possible for Rydberg states in atoms with a stronger blockade, longer lifetimes, and larger Rabi frequencies.