No-go theorem for ground state cooling given initial system-thermal bath factorization

Ground-state cooling and pure state preparation of a small object that is embedded in a thermal environment is an important challenge and a highly desirable quantum technology. This paper proves, with two different methods, that a fundamental constraint on the cooling dynamic implies that it is impossible to cool, via a unitary system-bath quantum evolution, a system that is embedded in a thermal environment down to its ground state, if the initial state is a factorized product of system and bath states. The latter is a crucial but artificial assumption included in numerous tools that treat system-bath dynamics, such as master equation approaches and Kraus operator based methods. Adopting these approaches to address ground state and even approximate ground state cooling dynamics should therefore be done with caution, considering the fundamental theorem exposed in this work.

[1]  Pritchard,et al.  Atom cooling by time-dependent potentials. , 1992, Physical review. A, Atomic, molecular, and optical physics.

[2]  Yong Li,et al.  Nondeterministic ultrafast ground-state cooling of a mechanical resonator , 2011, 1103.4197.

[3]  Laser cooling of a nanomechanical resonator mode to its quantum ground state. , 2003, Physical review letters.

[4]  C. Monroe,et al.  Quantum dynamics of single trapped ions , 2003 .

[5]  Francesco Petruccione,et al.  The Theory of Open Quantum Systems , 2002 .

[6]  J. B. Hertzberg,et al.  Preparation and detection of a mechanical resonator near the ground state of motion , 2009, Nature.

[7]  R. Xu,et al.  Theory of open quantum systems , 2002 .

[8]  M. Hohenstatt,et al.  "Optical-sideband Cooling of Visible Atom Cloud Confined in Parabolic Well" , 1978 .

[9]  Wineland,et al.  Laser cooling to the zero-point energy of motion. , 1989, Physical review letters.

[10]  Optical pumping of quantum-dot nuclear spins. , 2003, Physical review letters.

[11]  T J Kippenberg,et al.  Theory of ground state cooling of a mechanical oscillator using dynamical backaction. , 2007, Physical review letters.

[12]  David J. Tannor,et al.  Laser cooling of internal degrees of freedom. II , 1997 .

[13]  Dominik Janzing,et al.  Thermodynamic limits of dynamic cooling. , 2011, Physical review. E, Statistical, nonlinear, and soft matter physics.

[14]  Khaled Karrai,et al.  Cavity cooling of a microlever , 2004, Nature.

[15]  Dirk C. Keene Acknowledgements , 1975 .

[16]  W. Zurek,et al.  Quantum discord: a measure of the quantumness of correlations. , 2001, Physical review letters.

[17]  F. Nori,et al.  Atomic physics and quantum optics using superconducting circuits , 2011, Nature.

[18]  Almut Beige,et al.  Rate-equation approach to cavity-mediated laser cooling , 2012, 1202.2992.

[19]  W. Wootters,et al.  A single quantum cannot be cloned , 1982, Nature.

[20]  O. Arcizet,et al.  Resolved Sideband Cooling of a Micromechanical Oscillator , 2007, 0709.4036.

[21]  M. Aspelmeyer,et al.  Laser cooling of a nanomechanical oscillator into its quantum ground state , 2011, Nature.