Quantification of non-Markovian effects in the Fenna-Matthews-Olson complex.
暂无分享,去创建一个
[1] J. Eckel,et al. Quantum coherent biomolecular energy transfer with spatially correlated fluctuations , 2010, 1003.3857.
[2] Alán Aspuru-Guzik,et al. Exciton-Phonon Information Flow in the Energy Transfer Process of Photosynthetic Complexes , 2010, 1011.3809.
[3] D. Chru'sci'nski,et al. Measures of non-Markovianity: Divisibility versus backflow of information , 2011, 1102.4318.
[4] S. Lloyd,et al. Environment-assisted quantum walks in photosynthetic energy transfer. , 2008, The Journal of chemical physics.
[5] R. Fox,et al. Quantum hysteresis and resonant tunneling in bistable systems , 1998 .
[6] E. Mucciolo,et al. Non-Markovian dynamics of double quantum dot charge qubits due to acoustic phonons , 2005 .
[7] Jyrki Piilo,et al. Witness for initial system-environment correlations in open-system dynamics , 2010, 1004.2184.
[8] Graham R Fleming,et al. Dynamics of light harvesting in photosynthesis. , 2009, Annual review of physical chemistry.
[9] S. Huelga,et al. Exploiting Structured Environments for Efficient Energy Transfer: The Phonon Antenna Mechanism. , 2012, The journal of physical chemistry letters.
[10] G. Fleming,et al. Quantum Coherence in Photosynthetic Light Harvesting , 2012 .
[11] P. Nalbach,et al. Multiphonon transitions in the biomolecular energy transfer dynamics. , 2010, The Journal of chemical physics.
[12] D. Braun,et al. Exciton transfer dynamics and quantumness of energy transfer in the Fenna-Matthews-Olson complex. , 2011, Physical review. E, Statistical, nonlinear, and soft matter physics.
[13] R. van Grondelle,et al. Revisiting the optical properties of the FMO protein , 2010, Photosynthesis Research.
[14] J. Cresser,et al. Comparing different non-Markovianity measures in a driven qubit system , 2010, 1011.5328.
[15] P. Nalbach,et al. Landau-Zener transitions in a dissipative environment: numerically exact results. , 2009, Physical review letters.
[16] M. Thorwart,et al. Coherent control of an effective two-level system in a non-Markovian biomolecular environment , 2009, 0903.2936.
[17] Graham R. Fleming,et al. Two-dimensional spectroscopy of electronic couplings in photosynthesis , 2005, Nature.
[18] G. Scholes,et al. Phonon-mediated path-interference in electronic energy transfer. , 2011, The Journal of chemical physics.
[19] Heinz-Peter Breuer,et al. Foundations and measures of quantum non-Markovianity , 2012, 1206.5346.
[20] H. Breuer,et al. Quantification of memory effects in the spin-boson model , 2012, 1207.5968.
[21] J Eisert,et al. Assessing non-Markovian quantum dynamics. , 2007, Physical review letters.
[22] Jian Zou,et al. Non-Markovianity of the damped Jaynes-Cummings model with detuning , 2010 .
[23] Hao-Sheng Zeng,et al. Non-Markovian dynamics for an open two-level system without rotating wave approximation: indivisibility versus backflow of information , 2012, 1205.6020.
[24] William K. Peters,et al. Electronic resonance with anticorrelated pigment vibrations drives photosynthetic energy transfer outside the adiabatic framework , 2012, Proceedings of the National Academy of Sciences.
[25] J. Sperling,et al. High frequency vibrational modulations in two-dimensional electronic spectra and their resemblance to electronic coherence signatures. , 2011, The journal of physical chemistry. B.
[26] Elsi-Mari Laine,et al. Markovianity and non-Markovianity in quantum and classical systems , 2011, 1106.0138.
[27] T. Renger,et al. The Eighth Bacteriochlorophyll Completes the Excitation Energy Funnel in the FMO Protein. , 2011, The journal of physical chemistry letters.
[28] M. Grifoni,et al. Dynamics of the spin-boson model with a structured environment , 2004 .
[29] John H. Reina,et al. Galactic Dynamics , 1995 .
[30] G. Guo,et al. Experimental control of the transition from Markovian to non-Markovian dynamics of open quantum systems , 2011, 1109.2677.
[31] G. Fleming,et al. On the adequacy of the Redfield equation and related approaches to the study of quantum dynamics in electronic energy transfer. , 2009, The Journal of chemical physics.
[32] Justin R Caram,et al. Long-lived quantum coherence in photosynthetic complexes at physiological temperature , 2010, Proceedings of the National Academy of Sciences.
[33] J. Piilo,et al. Initial correlations in open-systems dynamics: The Jaynes-Cummings model , 2010, 1010.4402.
[34] M. Paternostro,et al. Memory-keeping effects and forgetfulness in the dynamics of a qubit coupled to a spin chain , 2010, 1011.5653.
[35] Thomas Renger,et al. On the relation of protein dynamics and exciton relaxation in pigment–protein complexes: An estimation of the spectral density and a theory for the calculation of optical spectra , 2002 .
[36] M. Gross,et al. Membrane orientation of the FMO antenna protein from Chlorobaculum tepidum as determined by mass spectrometry-based footprinting , 2009, Proceedings of the National Academy of Sciences.
[37] D. Tronrud,et al. The structural basis for the difference in absorbance spectra for the FMO antenna protein from various green sulfur bacteria , 2009, Photosynthesis Research.
[38] P. Nalbach,et al. The role of discrete molecular modes in the coherent exciton dynamics in FMO , 2012 .
[39] Tõnu Pullerits,et al. Origin of Long-Lived Coherences in Light-Harvesting Complexes , 2012, The journal of physical chemistry. B.
[40] E. Peterman,et al. Electron-Phonon Coupling and Vibronic Fine Structure of Light-Harvesting Complex II of Green Plants: Temperature Dependent Absorption and High-Resolution Fluorescence Spectroscopy , 1997 .
[41] Javier Prior,et al. The role of non-equilibrium vibrational structures in electronic coherence and recoherence in pigment–protein complexes , 2013, Nature Physics.
[42] Tobias Kramer,et al. Disentangling electronic and vibronic coherences in two-dimensional echo spectra. , 2013, The journal of physical chemistry. B.
[43] T. Renger,et al. How proteins trigger excitation energy transfer in the FMO complex of green sulfur bacteria. , 2006, Biophysical journal.
[44] Gregory S. Engel,et al. Quantum coherence spectroscopy reveals complex dynamics in bacterial light-harvesting complex 2 (LH2) , 2012, Proceedings of the National Academy of Sciences.
[45] Milosz A. Przyjalgowski,et al. Electron-vibrational coupling in the Fenna-Matthews-Olson complex of Prosthecochloris aestuarii determined by temperature dependent absorption and fluorescence line narrowing measurements , 2000 .
[46] Hao-Sheng Zeng,et al. Equivalence of the measures of non-Markovianity for open two-level systems , 2011, 1104.0070.
[47] Elsi-Mari Laine,et al. Phenomenological memory-kernel master equations and time-dependent Markovian processes , 2010, 1003.3817.
[48] Donatas Zigmantas,et al. Coherent picosecond exciton dynamics in a photosynthetic reaction center. , 2012, Journal of the American Chemical Society.
[49] C. Kreisbeck,et al. Long-Lived Electronic Coherence in Dissipative Exciton Dynamics of Light-Harvesting Complexes , 2012, 1203.1485.
[50] Christoph Meier,et al. Non-Markovian evolution of the density operator in the presence of strong laser fields , 1999 .
[51] M. B. Plenio,et al. Dephasing-assisted transport: quantum networks and biomolecules , 2008, 0807.4902.
[52] T. Mančal,et al. Enhancement of Vibronic and Ground-State Vibrational Coherences in 2D Spectra of Photosynthetic Complexes , 2012, Scientific Reports.
[53] K. Schulten,et al. The FMO complex in a glycerol-water mixture. , 2013, The journal of physical chemistry. B.
[54] Sabrina Maniscalco,et al. Non-Markovian Dynamics of a Damped Driven Two-State System , 2010, 1001.3564.
[55] U. Kleinekathöfer,et al. Time-dependent atomistic view on the electronic relaxation in light-harvesting system II. , 2010, The journal of physical chemistry. B.
[56] Guang-Can Guo,et al. Measuring non-Markovianity of processes with controllable system-environment interaction , 2011, 1109.2438.
[57] N. Makri,et al. Tensor propagator for iterative quantum time evolution of reduced density matrices. II. Numerical methodology , 1995 .
[58] G. Fleming,et al. Unified treatment of quantum coherent and incoherent hopping dynamics in electronic energy transfer: reduced hierarchy equation approach. , 2009, The Journal of chemical physics.
[59] M. Znidaric,et al. Excitation energy transfer efficiency: equivalence of transient and stationary setting and the absence of non-Markovian effects. , 2013, The Journal of chemical physics.
[60] Jyrki Piilo,et al. Measure for the degree of non-markovian behavior of quantum processes in open systems. , 2009, Physical review letters.
[61] Susana F Huelga,et al. Entanglement and non-markovianity of quantum evolutions. , 2009, Physical review letters.
[62] N. Makri,et al. TENSOR PROPAGATOR FOR ITERATIVE QUANTUM TIME EVOLUTION OF REDUCED DENSITY MATRICES. I: THEORY , 1995 .
[63] Sabrina Maniscalco,et al. Quantifying, characterizing, and controlling information flow in ultracold atomic gases , 2011, 1105.4790.
[64] Guang-Can Guo,et al. Nonlocal memory effects in the dynamics of open quantum systems. , 2011, Physical review letters.
[65] Gregory D. Scholes,et al. Coherently wired light-harvesting in photosynthetic marine algae at ambient temperature , 2010, Nature.
[66] K. Schulten,et al. Theory and Simulation of the Environmental Effects on FMO Electronic Transitions. , 2011, The journal of physical chemistry letters.
[67] V. May,et al. Charge and Energy Transfer Dynamics in Molecular Systems: MAY:CHARGE TRANSFER 3ED O-BK , 2011 .
[68] T. Mančal,et al. Evidence for wavelike energy transfer through quantum coherence in photosynthetic systems , 2007, Nature.
[69] Jyrki Piilo,et al. Measure for the non-Markovianity of quantum processes , 2010, 1002.2583.
[70] P. Nalbach,et al. Organic π-conjugated copolymers as molecular charge qubits. , 2013, Physical review letters.
[71] Graham R. Fleming,et al. Iterative path-integral algorithm versus cumulant time-nonlocal master equation approach for dissipative biomolecular exciton transport , 2011 .