Title :
Scalable entanglement of trapped ions
Author :
Sackett, C.A. ; Kielpinski, D. ; Langer, Christoph ; Meyer, Vincent ; Rowe, Matthew ; Turchette, Q.A. ; Itano, W.M. ; Monroe, C. ; Wineland, D.J.
Author_Institution :
Time & Frequency Div., Nat. Inst. of Stand. & Technol., Boulder, CO, USA
Abstract :
Summary form only given. Quantum entanglement is a fundamental element of schemes for quantum communication, cryptography, and computation. In a previous experiment, we demonstrated that two-particle entanglement could be generated in a deterministic way using trapped ions. However, that scheme also could not easily be applied to more particles in a single trap, because it relied on the particular behavior of two ions in a quadrupole RF trap. We have now demonstrated a truly scalable entanglement technique. The scheme is that of a recent proposal by Molmer and Sorensen. Twog /sup 9/Be/sub +/ ions are confined in a linear RF trap, and laser-cooled to near their motional ground state. Lasers are then used to drive Raman transitions between two ground-state hyperfine levels, which are separated by energy hw/sub o/.
Keywords :
beryllium; hyperfine structure; laser cooling; probability; quantum cryptography; /sup 9/Be/sub +/ ions; Be; Raman transitions; cryptography; ground-state hyperfine levels; laser-cooled; linear RF trap; motional ground state; optical computation; quadrupole RF trap; quantum communication; quantum entanglement; scalable entanglement; trapped ions; truly scalable entanglement technique; Quantum entanglement;
Conference_Titel :
Quantum Electronics and Laser Science Conference, 2000. (QELS 2000). Technical Digest
Conference_Location :
San Francisco, CA, USA
Print_ISBN :
1-55752-608-7
