| How proteins trigger excitation energy transfer in the FMO complex of green sulfur bacteria J Adolphs, T Renger Biophysical journal 91 (8), 2778-2797, 2006 | 816 | 2006 |
| Intermolecular Coulomb couplings from ab initio electrostatic potentials: application to optical transitions of strongly coupled pigments in photosynthetic antennae and … ME Madjet, A Abdurahman, T Renger The Journal of Physical Chemistry B 110 (34), 17268-17281, 2006 | 468 | 2006 |
| Ultrafast excitation energy transfer dynamics in photosynthetic pigment–protein complexes T Renger, V May, O Kühn Physics Reports 343 (3), 137-254, 2001 | 467 | 2001 |
| Quantum biology revisited J Cao, RJ Cogdell, DF Coker, HG Duan, J Hauer, U Kleinekathöfer, ... Science Advances 6 (14), eaaz4888, 2020 | 449 | 2020 |
| 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 T Renger, RA Marcus The Journal of chemical physics 116 (22), 9997-10019, 2002 | 408 | 2002 |
| Photosystem II: The machinery of photosynthetic water splitting G Renger, T Renger Photosynthesis research 98 (1), 53-80, 2008 | 358 | 2008 |
| Light harvesting in photosystem II core complexes is limited by the transfer to the trap: can the core complex turn into a photoprotective mode? G Raszewski, T Renger Journal of the American Chemical Society 130 (13), 4431-4446, 2008 | 252 | 2008 |
| The eighth bacteriochlorophyll completes the excitation energy funnel in the FMO protein M Schmidt am Busch, F Müh, M El-Amine Madjet, T Renger The journal of physical chemistry letters 2 (2), 93-98, 2011 | 249 | 2011 |
| α-Helices direct excitation energy flow in the Fenna–Matthews–Olson protein F Müh, MEA Madjet, J Adolphs, A Abdurahman, B Rabenstein, H Ishikita, ... Proceedings of the National Academy of Sciences 104 (43), 16862-16867, 2007 | 245 | 2007 |
| Calculation of pigment transition energies in the FMO protein: From simplicity to complexity and back J Adolphs, F Müh, MEA Madjet, T Renger Photosynthesis research 95, 197-209, 2008 | 226 | 2008 |
| Theory of excitation energy transfer: from structure to function T Renger Photosynthesis research 102, 471-485, 2009 | 223 | 2009 |
| Theory of optical spectra of photosystem II reaction centers: location of the triplet state and the identity of the primary electron donor G Raszewski, W Saenger, T Renger Biophysical Journal 88 (2), 986-998, 2005 | 220 | 2005 |
| Structure-based identification of energy sinks in plant light-harvesting complex II F Müh, MEA Madjet, T Renger The Journal of Physical Chemistry B 114 (42), 13517-13535, 2010 | 196 | 2010 |
| Understanding photosynthetic light-harvesting: a bottom up theoretical approach T Renger, F Müh Physical Chemistry Chemical Physics 15 (10), 3348-3371, 2013 | 181 | 2013 |
| Spectroscopic properties of reaction center pigments in photosystem II core complexes: revision of the multimer model G Raszewski, BA Diner, E Schlodder, T Renger Biophysical journal 95 (1), 105-119, 2008 | 177 | 2008 |
| Variable-range hopping electron transfer through disordered bridge states: Application to DNA T Renger, RA Marcus The Journal of Physical Chemistry A 107 (41), 8404-8419, 2003 | 162 | 2003 |
| Photosystem II does not possess a simple excitation energy funnel: time-resolved fluorescence spectroscopy meets theory Y Shibata, S Nishi, K Kawakami, JR Shen, T Renger Journal of the American Chemical Society 135 (18), 6903-6914, 2013 | 141 | 2013 |
| Normal mode analysis of the spectral density of the Fenna–Matthews–Olson light-harvesting protein: how the protein dissipates the excess energy of excitons T Renger, A Klinger, F Steinecker, M Schmidt am Busch, J Numata, ... The Journal of Physical Chemistry B 116 (50), 14565-14580, 2012 | 137 | 2012 |
| Structure-based calculations of optical spectra of photosystem I suggest an asymmetric light-harvesting process J Adolphs, F Müh, MEA Madjet, M Schmidt am Busch, T Renger Journal of the American Chemical Society 132 (10), 3331-3343, 2010 | 134 | 2010 |
| Theory of Optical Spectra Involving Charge Transfer States: Dynamic Localization Predicts<? format?> a Temperature Dependent Optical Band Shift T Renger Physical review letters 93 (18), 188101, 2004 | 132 | 2004 |
