Primary processes in bacterial reaction center revealed by femtosecond broadband fluorescence spectroscopy

To gain a deeper understanding of the highly efficient mechanisms within the photosynthetic bacterial reaction center (BRC), we have employed femtosecond broadband fluorescence spectroscopy to investigate the dynamics of initial photo-induced energy transfer and charge separation in BRC at room temperature. Benefiting from the broadband spectral coverage inherent of this technique, two distinct transient emission species associated with bacteriochlorophylls B and P are directly identified, with Stokes shifts determined to be ~197 and 450 cm−1, respectively. The ultrafast energy transfers from bacteriopheophytin H to B (98 fs) and from B to P (170 fs) are unveiled through fitting the emission dynamics. Notably, the anticipated sub-200 fs lifetime of B emission significantly extends to ~400 fs, suggesting a plausible coupling between the electronic excited state of Band the vibronic states of P, potentially influencing the acceleration of the energy transfer process. These findings should pave the way for understanding the impact of vibronic dynamics on the photo-induced primary processes in the photosynthetic reaction center.