Ultrafast multi-pulse transient absorption spectroscopy of fucoxanthin chlorophyll a protein from Phaeodactylum tricornutum

We have applied femtosecond transient absorption spectroscopy in pump-probe and pump-dump-probe regimes to study energy transfer between fucoxanthin and Chl a in fucoxanthin-Chl a complex from the pennate diatom Phaeodactylum tricornutum. Experiments were carried out at room temperature and 77?K to reveal temperature dependence of energy transfer. At both temperatures, the ultrafast (<100?fs) energy transfer channel from the fucoxanthin S₂ state is active and is complemented by the second pathway via the combined S₁/ICT state. The S₁/ICT-Chl a pathway has two channels, the fast one characterized by sub-picosecond energy transfer, and slow having time constants of 4.5?ps at room temperature and 6.6?ps at 77?K. The overall energy transfer via the S₁/ICT is faster at 77?K, because the fast component gains amplitude upon lowering the temperature. The pump-dump-probe regime, with the dump pulse centered in the spectral region of ICT stimulated emission at 950?nm and applied at 2?ps after excitation, proved that the S₁ and ICT states of fucoxanthin in FCP are individual, yet coupled entities. Analysis of the pump-dump-probe data suggested that the main energy donor in the slow S₁/ICT-Chl a route is the S₁ part of the S₁/ICT potential surface.