Non-Markovian Dynamics of Open Quantum Systems

Title of dissertation: NON-MARKOVIAN DYNAMICS OF OPEN QUANTUM SYSTEMS Chris H. Fleming, Doctor of Philosophy, 2011 Dissertation directed by: Professor Bei-Lok Hu Department of Physics An open quantum system is a quantum system that interacts with some environment whose degrees of freedom have been coarse grained away. This model describes non-equilibrium processes more general than scattering-matrix formulations. Furthermore, the microscopically-derived environment provides a model of noise, dissipation and decoherence far more general than Markovian (white noise) models. The latter are fully characterized by Lindblad equations and can be motivated phenomenologically. Non-Markovian processes consistently account for backreaction with the environment and can incorporate effects such as finite temperature and spatial correlations. We consider linear systems with bilinear coupling to the environment, or quantum Brownian motion, and nonlinear systems with weak coupling to the environment. For linear systems we provide exact solutions with analytical results for a variety of spectral densities. Furthermore, we point out an important mathematical subtlety which led to incorrect master-equation coefficients in earlier derivations, given nonlocal dissipation. For nonlinear systems we provide perturbative solutions by translating the formalism of canonical perturbation theory into the context of master equations. It is shown that unavoidable degeneracy causes an unfortunate reduction in accuracy between perturbative master equations and their solutions. We also extend the famous theorem of Lindblad, Gorini, Kossakowski and Sudarshan on completely positivity to non-Markovian master equations. Our application is primarily to model atoms interacting via a common electromagnetic field. The electromagnetic field contains correlations in both space and time, which are related to its relativistic (photon-mediated) nature. As such, atoms residing in the same field experience different environmental effects depending upon their relative position and orientation. Our more accurate solutions were necessary to assess sudden death of entanglement at zero temperature. In contrast to previous claims, we found that all initial states of two-level atoms undergo finite-time disentanglement. We were also able to access regimes which cannot be described by Lindblad equations and other simpler methods, such as near resonance. Finally we revisit the infamous Abraham-Lorentz force, wherein a single particle in motion experiences backreaction from the electromagnetic field. This leads to a number of well-known problems including pre-acceleration and runaway solutions. We found a more a more-suitable open-system treatment of the nonrelativistic particle to be perfectly causal and dissipative without any extraneous requirements for finite size of the particle, weak coupling to the field, etc.. NON-MARKOVIAN DYNAMICS OF OPEN QUANTUM SYSTEMS

[1]  E. Sudarshan,et al.  Completely Positive Dynamical Semigroups of N Level Systems , 1976 .

[2]  David H. Sharp,et al.  Radiation Reaction in Nonrelativistic Quantum Electrodynamics , 1977 .

[3]  Sabrina Maniscalco,et al.  Non-Markovian Dynamics of a Damped Driven Two-State System , 2010, 1001.3564.

[4]  J. Eberly,et al.  Pairwise concurrence dynamics: a four-qubit model , 2007, quant-ph/0701111.

[5]  A. Roura,et al.  Initial-state preparation with dynamically generated system-environment correlations. , 2011, Physical review. E, Statistical, nonlinear, and soft matter physics.

[6]  J. Piilo,et al.  Cavity losses for the dissipative Jaynes–Cummings Hamiltonian beyond rotating wave approximation , 2007, 0709.1614.

[7]  Semiclassical Klein-Kramers and Smoluchowski equations for the Brownian motion of a particle in an external potential , 2007 .

[8]  R. Ingarden,et al.  Information Dynamics and Open Systems: Classical and Quantum Approach , 1997 .

[9]  M. Wallquist,et al.  Single-atom cavity QED and optomicromechanics , 2009, 0912.4424.

[10]  鈴木 増雄 Time-Dependent Statistics of the Ising Model , 1965 .

[11]  B. Camarota,et al.  Approaching the Quantum Limit of a Nanomechanical Resonator , 2004, Science.

[12]  Francesco Petruccione,et al.  The Time-Convolutionless Projection Operator Technique in the Quantum Theory of Dissipation and Decoherence , 2001 .

[13]  Paul Adrien Maurice Dirac,et al.  Classical theory of radiating electrons , 1938 .

[14]  W. Zurek Decoherence and the Transition from Quantum to Classical—Revisited , 2003, quant-ph/0306072.

[15]  Dependence of the fluctuation-dissipation temperature on the choice of observable. , 2009, Physical review letters.

[16]  Stochastic Theory of Relativistic Particles Moving in a Quantum Field: II. Scalar Abraham-Lorentz-Dirac-Langevin Equation, Radiation Reaction and Vacuum Fluctuations , 2000, quant-ph/0101001.

[17]  Pierre Meystre,et al.  Atom Optics , 2001 .

[18]  H. Sommers,et al.  Bures volume of the set of mixed quantum states , 2003, quant-ph/0304041.

[19]  Strong friction limit in quantum mechanics: the quantum Smoluchowski equation. , 2001, Physical review letters.

[20]  Augusto J. Roncaglia,et al.  Dynamical phases for the evolution of the entanglement between two oscillators coupled to the same environment , 2008, 0809.1676.

[21]  W. Zurek Decoherence, einselection, and the quantum origins of the classical , 2001, quant-ph/0105127.

[22]  F. Rohrlich,et al.  The dynamics of a charged sphere and the electron , 1997 .

[23]  J. Cirac,et al.  Quantum Computations with Cold Trapped Ions. , 1995, Physical review letters.

[24]  I. Stamatescu,et al.  Decoherence and the Appearance of a Classical World in Quantum Theory , 1996 .

[25]  The limits of the rotating wave approximation in electromagnetic field propagation in a cavity , 2005, quant-ph/0512146.

[26]  M. Sentís Quantum theory of open systems , 2002 .

[27]  DECOHERENCE AND INITIAL CORRELATIONS IN QUANTUM BROWNIAN MOTION , 1996, quant-ph/9612036.

[28]  Ting Yu,et al.  Convolutionless Non-Markovian master equations and quantum trajectories: Brownian motion , 2004 .

[29]  Englert,et al.  Quantum optical master equations: The use of damping bases. , 1993, Physical review. A, Atomic, molecular, and optical physics.

[30]  Homi Jehangir Bhabha,et al.  Classical theory of electrons , 1939 .

[31]  A. Leggett,et al.  Quantum tunnelling in a dissipative system , 1983 .

[32]  R. Bhatia Positive Definite Matrices , 2007 .

[33]  Halliwell,et al.  Generalized uncertainty relations and long-time limits for quantum Brownian motion models. , 1995, Physical review. D, Particles and fields.

[34]  Quantum Limit of Decoherence: Environment Induced Superselection of Energy Eigenstates , 1998, quant-ph/9811026.

[35]  A. Dijkstra,et al.  Non-Markovian entanglement dynamics in the presence of system-bath coherence. , 2010, Physical review letters.

[36]  Theory of Many-Particle Systems , 1989 .

[37]  R. Zwanzig Ensemble Method in the Theory of Irreversibility , 1960 .

[38]  G. W. Ford,et al.  Exact solution of the Hu-Paz-Zhang master equation , 2001 .

[39]  Ford,et al.  On the quantum langevin equation , 1981, Physical review. A, General physics.

[40]  Simón Peres-horodecki separability criterion for continuous variable systems , 1999, Physical review letters.

[41]  Radiation reaction of a classical quasi-rigid extended particle , 2005, physics/0508031.

[42]  D. Tannor,et al.  On the second-order corrections to the quantum canonical equilibrium density matrix , 2000 .

[43]  Igor Volovich,et al.  Quantum Theory and Its Stochastic Limit , 2002 .

[44]  Caldeira,et al.  Quantum mechanics of radiation damping. , 1991, Physical review. A, Atomic, molecular, and optical physics.

[45]  C. H. Fleming,et al.  Quantum Brownian motion of multipartite systems and their entanglement dynamics , 2011 .

[46]  Göran Lindblad,et al.  Non-equilibrium entropy and irreversibility , 1983 .

[47]  F. Casas,et al.  Floquet theory: exponential perturbative treatment , 2001 .

[48]  J. Paz,et al.  Dynamics of the entanglement between two oscillators in the same environment. , 2008, Physical review letters.

[49]  S. Swain Master equation derivation of quantum regression theorem , 1981 .

[50]  A. Clerk,et al.  Nonlocality and the Rotating Wave Approximation , 1998 .

[51]  B. Hu,et al.  Two-Level Atom-Field Interaction: Exact Master Equations for Non-Markovian Dynamics, Decoherence and Relaxation , 1999, quant-ph/9901078.

[52]  D. Matsukevich,et al.  Entanglement of single-atom quantum bits at a distance , 2007, Nature.

[53]  S. Nakajima,et al.  On Quantum Theory of Transport Phenomena , 1959 .

[54]  Bei-Lok Hu,et al.  Non-Markovian entanglement dynamics of two qubits interacting with a common electromagnetic field , 2009, Quantum Inf. Process..

[55]  E. M. Lifshitz,et al.  Classical theory of fields , 1952 .

[56]  A. Kossakowski,et al.  On quantum statistical mechanics of non-Hamiltonian systems , 1972 .

[57]  M. Horodecki,et al.  Dynamics of quantum entanglement , 2000, quant-ph/0008115.

[58]  Steven A. Adelman,et al.  Fokker-Planck equations for simple non-Markovian systems , 1976 .

[59]  Rangarajan,et al.  General moment invariants for linear Hamiltonian systems. , 1992, Physical review. A, Atomic, molecular, and optical physics.

[60]  P. Cui,et al.  Non-Markovian Quantum Dissipation in the Presence of External Fields , 2003 .

[61]  T. Yu,et al.  Finite-time disentanglement via spontaneous emission. , 2004, Physical review letters.

[62]  N. Kampen,et al.  Langevin and master equation in quantum mechanics , 1997 .

[63]  C. cohen-tannoudji,et al.  Photons and Atoms: Introduction to Quantum Electrodynamics , 1989 .

[64]  S. Miyashita,et al.  Dynamics of the Density Matrix in Contact with a Thermal Bath and the Quantum Master Equation , 2008, 0810.0626.

[65]  M. Fleischhauer Quantum-theory of photodetection without the rotating wave approximation , 1998 .

[66]  V. I. Tatarskii Corrections to the theory of photocounting , 1990, Annual Meeting Optical Society of America.

[67]  K. Lendi,et al.  Quantum Dynamical Semigroups and Applications , 1987 .

[68]  Chen,et al.  Dissipative quantum dynamics in a boson bath. , 1989, Physical review. B, Condensed matter.

[69]  G. Agarwal Quantum statistical theories of spontaneous emission and their relation to other approaches , 1974 .

[70]  D. Petz,et al.  Geometries of quantum states , 1996 .

[71]  Gert-Ludwig Ingold,et al.  Quantum Brownian motion: The functional integral approach , 1988 .

[72]  Paz,et al.  Quantum Brownian motion in a general environment. II. Nonlinear coupling and perturbative approach. , 1993, Physical review. D, Particles and fields.

[73]  Zurek,et al.  Reduction of a wave packet in quantum Brownian motion. , 1989, Physical review. D, Particles and fields.

[74]  E. Calzetta,et al.  Nonequilibrium quantum field theory , 2008 .

[75]  Enric Verdaguer,et al.  Stochastic description for open quantum systems , 2000 .

[76]  C. J. Eliezer On the classical theory of particles , 1948, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[77]  H. Carmichael Statistical Methods in Quantum Optics 2 , 2008 .

[78]  Man-Duen Choi Completely positive linear maps on complex matrices , 1975 .

[79]  Hakim,et al.  Quantum theory of a free particle interacting with a linearly dissipative environment. , 1985, Physical review. A, General physics.

[80]  Quantum Entanglement under Non-Markovian Dynamics of Two Qubits Interacting with a common Electromagnetic Field , 2006, quant-ph/0610007.

[81]  Marcelo O. Terra Cunha The geometry of entanglement sudden death , 2007 .

[82]  A. Roura,et al.  de Sitter spacetime , 2022 .

[83]  R. Feynman,et al.  The Theory of a general quantum system interacting with a linear dissipative system , 1963 .

[84]  J Rosyx Magnus and Fer expansions for matrix differential equations: the convergence problem , 1998 .

[85]  A. Roura,et al.  Master Equation for Quantum Brownian Motion Derived by Stochastic Methods , 2001, gr-qc/0103037.

[86]  G. Vidal,et al.  Computable measure of entanglement , 2001, quant-ph/0102117.

[87]  James,et al.  Photodetection and causality in quantum optics. , 1995, Physical review. A, Atomic, molecular, and optical physics.

[88]  A. Roura,et al.  Stability of de Sitter spacetime under isotropic perturbations in semiclassical gravity , 2007, 0712.2282.

[89]  H. P. Robertson An Indeterminacy Relation for Several Observables and Its Classical Interpretation , 1934 .

[90]  K. Friedrichs On the perturbation of continuous spectra , 1948 .

[91]  Edward Davies Quantum dynamical semigroups and the neutron diffusion equation , 1977 .

[92]  C. Fleming,et al.  Accuracy of perturbative master equations. , 2010, Physical review. E, Statistical, nonlinear, and soft matter physics.

[93]  W. Magnus On the exponential solution of differential equations for a linear operator , 1954 .

[94]  E. Sudarshan,et al.  Who's afraid of not completely positive maps? , 2005 .

[95]  J. Raimond,et al.  Manipulating quantum entanglement with atoms and photons in a cavity , 2001 .

[96]  Arthur D. Yaghjian,et al.  Relativistic dynamics of a charged sphere : updating the Lorentz-Abraham model , 1992 .

[97]  Herbert Spohn,et al.  The critical manifold of the Lorentz-Dirac equation , 2000 .

[98]  T. Yu,et al.  Sudden death of entanglement of two Jaynes–Cummings atoms , 2006, quant-ph/0602206.

[99]  Habib,et al.  Reduction of the wave packet: Preferred observable and decoherence time scale. , 1993, Physical review. D, Particles and fields.

[100]  Yanbei Chen,et al.  Quantum noise in second generation, signal recycled laser interferometric gravitational wave detectors , 2001 .

[101]  R. Rosenfeld Nature , 2009, Otolaryngology--head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery.

[102]  Deconstructing Decoherence , 1996, quant-ph/9611045.

[103]  I. D. Vega,et al.  Non-Markovian reduced propagator, multiple-time correlation functions, and master equations with general initial conditions in the weak-coupling limit , 2006 .

[104]  C. cohen-tannoudji,et al.  Vacuum fluctuations and radiation reaction : identification of their respective contributions , 1982 .

[105]  Maira Amezcua,et al.  Quantum Optics , 2012 .

[106]  Pechukas,et al.  Reduced dynamics need not be completely positive. , 1994, Physical review letters.

[107]  Anthony K. Felts,et al.  The Redfield Equation in Condensed‐Phase Quantum Dynamics , 2007 .

[108]  J. Kirkwood The statistical mechanical theory of irreversible processes , 1949 .

[109]  Paz,et al.  Quantum Brownian motion in a general environment: Exact master equation with nonlocal dissipation and colored noise. , 1992, Physical review. D, Particles and fields.

[110]  ENERGY FLOW, PARTIAL EQUILIBRATION, AND EFFECTIVE TEMPERATURES IN SYSTEMS WITH SLOW DYNAMICS , 1997, cond-mat/9611044.

[111]  D. A. Dunnett Classical Electrodynamics , 2020, Nature.

[112]  D. A. Trifonov Generalizations of Heisenberg uncertainty relation , 2001 .

[113]  T. Yu,et al.  Sudden Death of Entanglement , 2009, Science.

[114]  G. Nienhuis,et al.  Derivation of a Hamiltonian for photon decay in a cavity , 2000 .

[115]  Collett,et al.  Input and output in damped quantum systems: Quantum stochastic differential equations and the master equation. , 1985, Physical review. A, General physics.

[116]  C. H. Fleming,et al.  Exact analytical solutions to the master equation of quantum Brownian motion for a general environment , 2010, 1004.1603.

[117]  Andrey B. Matsko,et al.  Conversion of conventional gravitational-wave interferometers into quantum nondemolition interferometers by modifying their input and/or output optics , 2001 .

[118]  G. W. Ford,et al.  RADIATION REACTION IN ELECTRODYNAMICS AND THE ELIMINATION OF RUNAWAY SOLUTIONS , 1991 .

[119]  Alain Joye,et al.  Open quantum systems , 2006 .

[120]  Anthony J Leggett,et al.  Influence of Dissipation on Quantum Tunneling in Macroscopic Systems , 1981 .

[121]  R. Dicke Coherence in Spontaneous Radiation Processes , 1954 .

[122]  Entropy and uncertainty of squeezed quantum open systems , 1997 .

[123]  Chen Ling,et al.  Biquadratic Optimization Over Unit Spheres and Semidefinite Programming Relaxations , 2009, SIAM J. Optim..

[124]  Quantum Brownian motion in a bath of parametric oscillators: A model for system-field interactions. , 1993, Physical review. D, Particles and fields.

[125]  Induced quantum metric fluctuations and the validity of semiclassical gravity , 2004, gr-qc/0402029.

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

[127]  E. Davies,et al.  Markovian master equations , 1974 .

[128]  G. Agarwal Rotating-Wave Approximation and Spontaneous Emission , 1971 .

[129]  G. Lindblad On the generators of quantum dynamical semigroups , 1976 .

[130]  G. Milburn,et al.  Quantum Measurement and Control , 2009 .

[131]  G. W. Ford,et al.  The rotating wave approximation (RWA) of quantum optics: serious defect , 1997 .

[132]  Peter W. Milonni,et al.  The Quantum Vacuum: An Introduction to Quantum Electrodynamics , 1993 .

[133]  A. Faessler,et al.  Weyl’s symbols of Heisenberg operators of canonical coordinates and momenta as quantum characteristics , 2006, quant-ph/0604075.

[134]  On the rotating wave approximation , 1984 .

[135]  Halliwell,et al.  Alternative derivation of the Hu-Paz-Zhang master equation of quantum Brownian motion. , 1996, Physical review. D, Particles and fields.

[136]  W. Wootters Entanglement of Formation of an Arbitrary State of Two Qubits , 1997, quant-ph/9709029.

[137]  B. Hu,et al.  Temporal and spatial dependence of quantum entanglement from a field theory perspective , 2008, 0812.4391.

[138]  V. Anderson,et al.  Information-theoretic measure of uncertainty due to quantum and thermal fluctuations. , 1993, Physical review. D, Particles and fields.

[139]  A. Leggett,et al.  Dynamics of the dissipative two-state system , 1987 .

[140]  E. Lutz,et al.  Decoherence in a nonequilibrium environment , 2010, 1004.3921.

[141]  J. Piilo,et al.  Microscopic derivation of the Jaynes-Cummings model with cavity losses , 2006, quant-ph/0610140.

[142]  A. Leggett,et al.  Path integral approach to quantum Brownian motion , 1983 .

[143]  U. Weiss Quantum Dissipative Systems , 1993 .