In the laser excitation of ultracold atoms to Rydberg states, we observe a dramatic suppression caused by van der Waals interactions. This behavior is interpreted as a local excitation blockade: Rydberg atoms strongly inhibit excitation of their neighbors. We measure suppression, relative to isolated atom excitation, by up to a factor of 6.4. The dependence of this suppression on both laser irradiance and atomic density are in good agreement with a mean-field model. These results are an important step towards using ultracold Rydberg atoms in quantum information processing.PACS numbers: 32.80. Rm, 03.67.Lx, 34.20.Cf The possibility of a computer that operates according to the principles of quantum mechanics has attracted growing interest from a variety of research fields [1,2]. A number of possible implementations are being investigated, including solid-state systems, nuclear magnetic resonance, cavity quantum electrodynamics, trapped dipolar molecules, trapped ions, and trapped neutral atoms. A key element to any successful system is the ability to control the coherent interactions between the fundamental building blocks (qubits). Highly-excited Rydberg atoms with principal quantum numbers n 30 have the advantage that they interact quite strongly with each other, allowing information to be exchanged quickly [3]. Here we report an important advance towards using ultracold Rydberg atoms in quantum computing. We observe that the laser excitation of a macroscopic sample of ultracold atoms to high-lying Rydberg states can be dramatically suppressed by their strong long-range interactions. This leads to a local blockade effect, where the excitation of one atom prevents excitation of its neighbors. Our observations agree well with a model based on mean-field interactions.In a high-n Rydberg state, the electron spends most of its time quite far from the nucleus [4]. As a result, the energy of this highly-excited state is very sensitive to external perturbations, including those caused by neighboring Rydberg atoms. A system of two ultracold Rydberg atoms, subject to these long-range interactions, has been proposed as a possible realization of a quantum logic gate [3,5]. Rydberg states combine the advantages of long radiative lifetimes and strong long-range interactions, allowing information to be exchanged before decoherence sets in, even when the atoms are sufficiently separated to allow individual addressing. If the atoms are ultracold, they can be highly localized, e.g., in the sites of an optical lattice, allowing control of their interactions and efficient detection of their quantum state. An outstanding challenge is the assurance that at most a single Rydberg atom is produced at a given site. Towards this end, the concept of an excitation blockade has been proposed [6,7]. With multiple atoms occupying a sufficiently localized site, the strong Rydberg-Rydberg interactions allow at most one Rydberg excitation. Further excitations are blocked by the large energy level shifts that push the resonant frequencies outsi...
