Previous experimental studies on a modified cytochrome c have shown that optical hole widths have a powerlaw dependence on waiting time. We show that a phenomenological model, which assumes Gaussian random frequency fluctuations whose two-point time-correlation function is a stretched exponential, is consistent with the experimental data.Optical spectroscopy has proven to be a useful technique for probing the dynamics of proteins at low temperatures. 1 In this paper, we are concerned with recent optical hole burning experiments on protoporphyrin IX-substituted cytochrome c in dimethylformamide/glycerol glass, performed by Fritsch et al. 2 at 4 K. In these experiments, the optical transition of the chromophore (protoporphyrin IX) is inhomogeneously broadened and a narrow-band laser is used to selectively excite only a small fraction of the chromophores (those on resonance with the laser). Some of the excited molecules undergo a photochemical reaction, and the photoproduct absorbs light in a spectral region different from the chromophore. Therefore, when the chromophore's absorption line shape is subsequently scanned, a dip or "hole" appears at the frequency of the burning laser.In a waiting time experiment, the width of the hole is measured as a function of the waiting time, t w , between burning and scanning. Typically, the hole width increases with t w as a result of "spectral diffusion". That is, the transition frequency of an individual chromophore is not static in time, but rather fluctuates due to changes in the chromophore's local environment. As the ensemble of chromophores evolves in time, this leads to a broadening of the hole. In particular, this experiment measures the convolution of the initial hole shape with the waiting-time-dependent "spectral diffusion kernel". The latter is the conditional probability density that a chromophore has a transition frequency ν at time t w given that it had transition frequency ν 0 at time 0.In the simplest scenario, both the initial hole and the (spectral diffusion) kernel are Lorentzian functions of frequency, in which case one can simply subtract the initial hole width from the hole width at t w to obtain the width of the kernel. And there is at least one physical model that leads to a Lorentzian kernel: when the chromophore is interacting in a dipolar manner with a collection of point defects 3 whose internal states change with time. A particular realization of this picture, believed to be appropriate for chromophores in glasses, takes the point defects to be two-level systems (TLS) whose energy asymmetries and tunneling matrix elements are widely distributed. [4][5][6][7] In the usual TLS model, it is known that the width of the kernel increases logarithmically with t w , and indeed, this t w dependence has been seen for many different chromophore/glass systems. 6 The protein experiments, when analyzed by assuming a Lorentzian kernel, show a power-law dependence of the width of the kernel on t w , with an exponent of about 1/2, 2 rather than the logarithmic depen...
