about
Evidence for wavelike energy transfer through quantum coherence in photosynthetic systemsCross-peak-specific two-dimensional electronic spectroscopy.Two-dimensional electronic spectroscopy reveals ultrafast energy diffusion in chlorosomes.System-Dependent Signatures of Electronic and Vibrational Coherences in Electronic Two-Dimensional Spectra.Origin of long-lived coherences in light-harvesting complexes.Enhancement of vibronic and ground-state vibrational coherences in 2D spectra of photosynthetic complexes.Robust light harvesting by a noisy antenna.Ultrafast energy transfer with competing channels: Non-equilibrium Förster and Modified Redfield theories.Vibronic coupling explains the ultrafast carotenoid-to-bacteriochlorophyll energy transfer in natural and artificial light harvesters.Exact stochastic unraveling of an optical coherence dynamics by cumulant expansion.Electronic coherence dephasing in excitonic molecular complexes: role of Markov and secular approximations.Signatures of Exciton Delocalization and Exciton-Exciton Annihilation in Fluorescence-Detected Two-Dimensional Coherent SpectroscopyFemtosecond laser pulse control of electron transfer processesTwo-dimensional electronic spectra of an aggregating dye: simultaneous measurement of monomeric and dimeric line-shapesUltrafast photo-induced charge transfer unveiled by two-dimensional electronic spectroscopyTwo-dimensional electronic spectroscopy of molecular excitonsInterpreting Fluorescence Detected Two-Dimensional Electronic SpectroscopyQuantum dissipation driven by electron transfer within a single molecule investigated with atomic force microscopyQuantum biology revisited
P50
Q28297712-528C420D-8AF4-4418-A188-357276AA4C3AQ33286691-6B08E199-1BA2-4CD6-A648-D5F429E74E08Q34280808-49CFA631-E987-4D61-B5ED-C24440B4E625Q40629900-0F62FC1E-BDC5-41AC-AC4C-75F61A74E6C3Q42959208-CF91134B-A677-417A-AB89-B823F39B2FC7Q43115311-C1A3CD72-8F25-45EB-B41F-6F0B3C3A3CABQ47556618-C70D99B6-E0DA-4F35-A826-F07B740B2424Q47857426-59F5429F-FFDC-47EE-B9C0-4C5636DA20FAQ50903109-21B22CB4-361B-4C0A-B302-4C409C7117EAQ51017576-07B5A566-1900-401C-9B4A-DED07098C434Q51680013-FA06138C-ECF7-48CF-93F7-ACBC244F782FQ57029225-B7C7924D-98AD-48E8-B04A-6E5E078F98DDQ57907402-2A10BA7A-58B1-4F79-811F-D9D919C3BF02Q84198559-49956ABF-26BA-4926-80B5-F3981EDD7038Q84297496-E05895DC-2E1A-4025-BBF7-D08579FB6CC6Q84391456-880970E5-EAEB-452E-99F5-233F18722254Q89553317-8666B9D8-7CF3-474A-B4EB-A9DBFA61F78EQ90281930-9ADB06D6-24DA-4717-95B6-BA8025B6AAA0Q91878515-37BA5368-D6D8-4517-94A1-5463D14127AD
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Tomáš Mančal
@ast
Tomáš Mančal
@en
Tomáš Mančal
@es
Tomáš Mančal
@nl
Tomáš Mančal
@sl
type
label
Tomáš Mančal
@ast
Tomáš Mančal
@en
Tomáš Mančal
@es
Tomáš Mančal
@nl
Tomáš Mančal
@sl
prefLabel
Tomáš Mančal
@ast
Tomáš Mančal
@en
Tomáš Mančal
@es
Tomáš Mančal
@nl
Tomáš Mančal
@sl
P1053
B-9688-2014
P106
P21
P31
P3829
P496
0000-0003-1736-3054