Center line slope (CLS) analysis
in 2D infrared spectroscopy has been extensively used to extract frequency–frequency
correlation functions of vibrational transitions. We apply this concept
to 2D electronic spectroscopy, where CLS is a measure of electronic
gap fluctuations. The two domains, infrared and electronic, possess
differences: In the infrared, the frequency fluctuations are classical,
often slow and Gaussian. In contrast, electronic spectra are subject
to fast spectral diffusion and affected by underdamped vibrational
wavepackets in addition to Stokes shift. All these effects result
in non-Gaussian peak profiles. Here, we extend CLS-analysis beyond
Gaussian line shapes and test the developed methodology on a solvated
molecule, zinc phthalocyanine. We find that CLS facilitates the interpretation
of 2D electronic spectra by reducing their complexity to one dimension.
In this way, CLS provides a highly sensitive measure of model parameters
describing electronic–vibrational and electronic–solvent
interaction.
The initial energy transfer steps in photosynthesis occur on ultrafast timescales. We analyze the carotenoid to bacteriochlorophyll energy transfer in LH2 Marichromatium purpuratum as well as in an artificial light-harvesting dyad system by using transient grating and two-dimensional electronic spectroscopy with 10 fs time resolution. We find that Förster-type models reproduce the experimentally observed 60 fs transfer times, but overestimate coupling constants, which lead to a disagreement with both linear absorption and electronic 2D-spectra. We show that a vibronic model, which treats carotenoid vibrations on both electronic ground and excited states as part of the system's Hamiltonian, reproduces all measured quantities. Importantly, the vibronic model presented here can explain the fast energy transfer rates with only moderate coupling constants, which are in agreement with structure based calculations. Counterintuitively, the vibrational levels on the carotenoid electronic ground state play the central role in the excited state population transfer to bacteriochlorophyll; resonance between the donor-acceptor energy gap and the vibrational ground state energies is the physical basis of the ultrafast energy transfer rates in these systems.
Long-lived oscillations in 2D spectra of chlorophylls are at the heart of an ongoing debate. Their physical origin is either a multipigment effect, such as excitonic coherence, or localized vibrations. We show how relative phase differences of diagonal- and cross-peak oscillations can distinguish between electronic and vibrational (vibronic) effects. While direct discrimination between the two scenarios is obscured when peaks overlap, their sensitivity to temperature provides a stronger argument. We show that vibrational (vibronic) oscillations change relative phase with temperature, while electronic oscillations are only weakly dependent. This highlights that studies of relative phase difference as a function of temperature provide a clear and easily accessible method to distinguish between vibrational and electronic coherences.
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