Controlling the quantum entanglement between parts of a many-body system is key to unlocking the power of quantum technologies such as quantum computation, high-precision sensing, and the simulation of many-body physics. The spin degrees of freedom of ultracold neutral atoms in their ground electronic state provide a natural platform for such applications thanks to their long coherence times and the ability to control them with magneto-optical fields. However, the creation of strong coherent coupling between spins has been challenging. Here we demonstrate a strong and tunable Rydberg-dressed interaction between spins of individually trapped caesium atoms with energy shifts of order 1 MHz in units of Planck's constant. This interaction leads to a ground-state spin-flip blockade, whereby simultaneous hyperfine spin flips of two atoms are inhibited owing to their mutual interaction. We employ this spin-flip blockade to rapidly produce single-step Bell-state entanglement between two atoms with a fidelity ≥81(2)%. P ristine quantum control of many-body correlations is fundamental to realizing the power of quantum information processors. Steady progress has continued in various platforms ranging from solid-state spintronics 1 and superconductors 2,3 to nanophotonics 4 and ultracold trapped atoms, both ionic 5-7 and neutral 8-10 . Cold neutral atoms are particularly attractive as the ability to create entanglement between atoms would allow for greatly increased precision of interferometers for applications in clocks 11-13 , and force sensors 14-16 . In addition, cold atoms provide a natural platform for quantum simulation of condensed-matter physics 17,18 and scalable digital quantum computers 19-21 . Controlled entanglement of neutral atoms, however, has been challenging, particularly if one seeks tunable interactions that are strong, coherent and long-range (∼µm).One mechanism to achieve strong, long-range coupling is the Rydberg blockade 22 . This has been successfully employed for implementing controlled entangling interactions between atoms 9,10,23 and quantum logic gates 24 . In the standard protocol, short pulses excite the population of one atom to the Rydberg state and optical excitation of a second atom is blockaded because of the electric dipole-dipole interaction 21 (EDDI). An alternative protocol is to adiabatically dress the ground state with the excited Rydberg state 25-27 . This Rydberg-dressed interaction enables tunable, anisotropic interactions that open the door to quantum simulations of a variety of exotic quantum phases 26,28,29 . In addition, it allows for quantum control of interacting atoms based solely on microwave/radiofrequency fields whose phase coherence is easily maintained. Applications include spin-squeezing for metrology 13,25 , and quantum computing 30,31 . Although the promise of Rydbergdressed interactions is great, experimental demonstration has been elusive. We present here a clear measurement of this interaction between two Rydberg-dressed atoms and employ coherent control in the ...
