Hatched and solid bars depict conceptually the portion of the contribution from a and b individually to the mixed states. Because μ and ν contain character of both a and b, they are correlated The method was applied to Bpheos (H band) and accessory BChls (B band) of the reaction center of Rb. sphaeroides

using pulses centered at 750 and 800 nm, yielding STA-9090 clinical trial an estimate of the coupling constant between them of ~170 ± 30 cm−1 (Parkinson et al. 2007). Another version of the two-color three-pulse photon echo experiment alternates colors in the pulse sequence to generate specific electronic coherences (two-color electronic coherence photon echo, 2CECPE) (Lee et al. 2007). A coherence between two excitonic states is prepared during T, whereas the 3PEPS experiments described above generate population states during T. Therefore, KU-57788 datasheet the photon echo signal along the T axis contains p38 MAPK cancer dynamics of quantum mechanical coherence between μ and ν, and between g and μ (or g and ν) along τ (see Fig. 4). Surprisingly long-lived (440 fs

at 77 K) electronic coherence between B and H was observed in the Rb. sphaeroides reaction centers with the primary electron donor chemically oxidized, suggesting that quantum coherence plays an important role in enhancing the efficiency of energy transfer in pigment–protein complexes. Lee et al. (2007) argued that correlated protein motion surrounding the pigments is essential to protect the quantum coherence, a mechanism that may be ubiquitous in photosynthetic machinery. The application of the 2CECPE technique to the bacterial reaction center shows how mechanistic details of photosynthetic systems can be obtained using photon echo methods. Two-dimensional

Fourier transform photon echo spectroscopy Principles of two-dimensional Fourier transform photon echo spectroscopy As demonstrated above, photon echo experiments afford control over multiple frequency and time “handles” (i.e., pulse color and duration of time periods T and τ). Furthermore, the Fourier relationship O-methylated flavonoid between time- and frequency-domain signals is of central importance, and can be exploited by researchers in the design of experiments. Whereas the frequency domain enables observation of excitation energy levels and transition strengths, the time domain allows direct measurement of dynamics. Adopting a time or frequency view accesses different types of information, and the various possibilities underlie the flexibility of photon echo-based techniques. Here we briefly outline the technique of two-dimensional (2D) Fourier transform photon echo spectroscopy, in which a mixed time/frequency view gives a wealth of information about the system of interest. A 2D spectrum graphs transitions along two frequency axes and contains information about correlation between transitions at different frequencies (Jonas 2003).