On the other hand, accumulated photon echo (APE) experiments on the same system (Lampoura et al. 2000) yielded values of Γhom at 4.2 K that were about five times smaller than those by Wu et al. (1997b). Lampoura et al. (2000) suggested that the discrepancy between the results from the APE experiments and HB experiments was due to spectral diffusion, since the experimental time scales in APE are much smaller than those in HB (picosecond vs. minutes, respectively). However, our HB results at 4.2 K coincide with those of the APE experiments, from which we conclude that the APE–HB discrepancy does not arise from spectral diffusion, but

is caused by the this website much too high burning fluences used in the HB experiments of Wu et al. (1997b). This shows that Γhom values extracted from HB experiments are reliable only find more when obtained from an extrapolation of the hole width to Pt/A → 0, as shown in Fig. 6a and b. Spectral diffusion: hole widths as a function of delay time The dependence of spectral diffusion on the size of photosynthetic complexes Proteins are materials that display both crystalline and glassy properties. On the one hand, they have rather well-defined tertiary structures reflected in their crystalline properties. On the other hand, and in contrast to crystals, the structures of proteins are not static: they

may undergo conformational changes between a large number of somewhat different intermediates called conformational sub-states (CSs; Frauenfelder et al. 1991, 2001; Friedrich et al. 1994; Hofmann et al. 2003; Rutkauskas et al. 2004, 2006). These CSs are separated by a wide distribution ZD1839 solubility dmso of energy SAHA chemical structure barriers with multiple minima on a potential energy landscape, reminiscent of TLSs in glasses. TLSs, however, are randomly distributed, whereas CSs are assumed to be hierarchically organized, possessing a large degree of complexity. Whether conformational changes in proteins have a continuous distribution of relaxation rates as observed in glasses (Koedijk et al. 1996; Littau et al. 1992; Meijers and Wiersma 1994; Silbey et al. 1996; Wannemacher et al. 1993), or are characterized by discrete and sharp rates (Thorn-Leeson

and Wiersma 1995; Thorn-Leeson et al. 1997), is still a controversial issue (Baier et al. 2007, 2008; Schlichter and Friedrich 2001; for reviews, see Berlin et al. 2006, 2007). One way to study the conformational dynamics of proteins is by following their time evolution through spectral diffusion (SD; Berlin et al. 2006; Creemers and Völker 2000; Den Hartog et al. 1999b; Richter et al. 2008; Schlichter and Friedrich 2001; Störkel et al. 1998). Here, we show that the size of the protein influences the amount of SD in photosynthetic pigment–protein complexes. We have investigated three sub-core complexes of photosystem II (PSII) of green plants (spinach) at low temperature by time-resolved spectral hole burning, covering 10 orders of magnitude in time (Den Hartog et al. 1999b; Groot et al.