. "Accounts of Chemical Research" . . . . "1"^^ . . "Milota, Franz" . . "US - Spojen\u00E9 st\u00E1ty americk\u00E9" . "RIV/00216208:11320/09:00206498!RIV10-GA0-11320___" . "Two-Dimensional Electronic Spectroscopy of Molecular Excitons" . . "P(GP202/07/P278), Z(MSM0021620835)" . "42" . "Two-Dimensional Electronic Spectroscopy of Molecular Excitons"@en . . "11"^^ . . "347191" . "Two-Dimensional Electronic Spectroscopy of Molecular Excitons"@en . "000269861400017" . . "11320" . . "Two-Dimensional Electronic Spectroscopy of Molecular Excitons" . "RIV/00216208:11320/09:00206498" . "Man\u010Dal, Tom\u00E1\u0161" . "Two-Dimensional; Electronic; Spectroscopy; Molecular; Excitons"@en . . "9" . . . "Nemeth, Alexandra" . "Sperling, Jaroslaw" . "[549CF80278E1]" . . . "0001-4842" . "In this Account, we summarize our studies of a series of increasingly complex molecular chromophores. We examine noninteracting dye molecules, a monomer-dimer equilibrium of a prototypical dye molecule, and finally a supramolecular assembly of electronically coupled absorbers. By tracing vibronic signal modulations, differentiating line-broadening mechanisms, analyzing distinctly different relaxation dynamics, determining electronic coupling strengths, and directly following excitation energy transfer pathways, we illustrate how two-dimensional electronic spectroscopy can image physical phenomena that underlie the optical response of a particular system."@en . "Kauffmann, Harald" . "5"^^ . "In this Account, we summarize our studies of a series of increasingly complex molecular chromophores. We examine noninteracting dye molecules, a monomer-dimer equilibrium of a prototypical dye molecule, and finally a supramolecular assembly of electronically coupled absorbers. By tracing vibronic signal modulations, differentiating line-broadening mechanisms, analyzing distinctly different relaxation dynamics, determining electronic coupling strengths, and directly following excitation energy transfer pathways, we illustrate how two-dimensional electronic spectroscopy can image physical phenomena that underlie the optical response of a particular system." . . . .