‘Designer atoms’ for quantum metrology

Entanglement is recognized as a key resource for quantum computation and quantum cryptography. For quantum metrology, the use of entangled states has been discussed and demonstrated as a means of improving the signal-to-noise ratio. In addition, entangled states have been used in experiments for efficient quantum state detection and for the measurement of scattering lengths. In quantum information processing, manipulation of individual quantum bits allows for the tailored design of specific states that are insensitive to the detrimental influences of an environment. Such ‘decoherence-free subspaces’ (ref. 10) protect quantum information and yield significantly enhanced coherence times. Here we use a decoherence-free subspace with specifically designed entangled states to demonstrate precision spectroscopy of a pair of trapped Ca+ ions; we obtain the electric quadrupole moment, which is of use for frequency standard applications. We find that entangled states are not only useful for enhancing the signal-to-noise ratio in frequency measurements—a suitably designed pair of atoms also allows clock measurements in the presence of strong technical noise. Our technique makes explicit use of non-locality as an entanglement property and provides an approach for ‘designed’ quantum metrology.

[1]  Entanglement interferometry for precision measurement of atomic scattering properties. , 2003, Physical review letters.

[2]  T Schneider,et al.  Sub-Hertz optical frequency comparisons between two trapped 171Yb+ ions. , 2005, Physical review letters.

[3]  H. Häffner,et al.  How to realize a universal quantum gate with trapped ions , 2003, quant-ph/0312162.

[4]  F. Schmidt-Kaler,et al.  Bell states of atoms with ultralong lifetimes and their tomographic state analysis. , 2004, Physical review letters.

[5]  J. Bernard,et al.  Electric quadrupole shift cancellation in single-ion optical frequency standards. , 2005, Physical review letters.

[6]  C Langer,et al.  Long-lived qubit memory using atomic ions. , 2005, Physical review letters.

[7]  Norman F. Ramsey,et al.  A Molecular Beam Resonance Method with Separated Oscillating Fields , 1950 .

[8]  C Langer,et al.  Spectroscopy Using Quantum Logic , 2005, Science.

[9]  Keiji Sasaki,et al.  Beating the Standard Quantum Limit with Four-Entangled Photons , 2007, Science.

[10]  A. Luiten Frequency Measurement and Control , 2001 .

[11]  H. Häffner,et al.  Robust entanglement , 2005 .

[12]  F. Schmidt-Kaler,et al.  Quantum State Engineering on an Optical Transition and Decoherence in a Paul Trap , 1999 .

[13]  S. Diddams,et al.  Standards of Time and Frequency at the Outset of the 21st Century , 2004, Science.

[14]  Gilles Brassard,et al.  Quantum Cryptography , 2005, Encyclopedia of Cryptography and Security.

[15]  W. Itano,et al.  Measurement of the (199)Hg+ 5d9 6s2 (2)D(5/2) electric quadrupole moment and a constraint on the quadrupole shift. , 2005, Physical review letters.

[16]  Wayne M. Itano,et al.  External-Field Shifts of the 199Hg+ Optical Frequency Standard , 2000, Journal of research of the National Institute of Standards and Technology.

[17]  D. Leibfried,et al.  Toward Heisenberg-Limited Spectroscopy with Multiparticle Entangled States , 2004, Science.

[18]  Alan A. Madej,et al.  Single-Ion Optical Frequency Standards and Measurement of their Absolute Optical Frequency , 2001 .

[19]  Wineland,et al.  Optimal frequency measurements with maximally correlated states. , 1996, Physical review. A, Atomic, molecular, and optical physics.

[20]  M. A. Rowe,et al.  A Decoherence-Free Quantum Memory Using Trapped Ions , 2001, Science.

[21]  P. Gill,et al.  Hertz-Level Measurement of the Optical Clock Frequency in a Single 88Sr+ Ion , 2004, Science.

[22]  S. Lloyd,et al.  Quantum-Enhanced Measurements: Beating the Standard Quantum Limit , 2004, Science.

[23]  Daniel A. Lidar,et al.  Decoherence-Free Subspaces for Quantum Computation , 1998, quant-ph/9807004.

[24]  S. Lloyd,et al.  Quantum metrology. , 2005, Physical review letters.

[25]  P Gill,et al.  Measurement of the electric quadrupole moment of the 4d2D5/2 level in 88Sr+. , 2004, Physical review letters.

[26]  Thierry Paul,et al.  Quantum computation and quantum information , 2007, Mathematical Structures in Computer Science.

[27]  W. Itano Quadrupole moments and hyperfine constants of metastable states of Ca{sup +}, Sr{sup +}, Ba{sup +}, Yb{sup +}, Hg{sup +}, and Au , 2005, physics/0512250.