To extract quantities of interest, the autocorrelation data can be fitted, typically using a
nonlinear least squares algorithm. The fit's functional form depends on the type of dynamics (and the optical geometry in question).
Normal diffusion The fluorescent particles used in FCS are small and thus experience thermal motions in solution. The simplest FCS experiment is thus normal 3D diffusion, for which the autocorrelation is: : \ G(\tau)=G(0)\frac{1}{(1+(\tau/\tau_D ))(1+a^{-2}(\tau/\tau_D ))^{1/2}} +G(\infty) where a=\omega_z/\omega_{xy} is the ratio of axial to radial e^{-2} radii of the measurement volume, and \tau_{D} is the characteristic residence time. This form was derived assuming a Gaussian measurement volume. Typically, the fit would have three free parameters—G(0), G(\infty), and \tau_D—from which the diffusion coefficient and fluorophore concentration can be obtained. With the normalization used in the previous section,
G(0) gives the mean number of diffusers in the volume , or equivalently—with knowledge of the observation volume size—the mean concentration: : \ G(0)=\frac{1}{\langle N\rangle}=\frac{1}{V_\text{eff}\langle C\rangle}, where the effective volume is found from integrating the Gaussian form of the measurement volume and is given by: : \ V_\text{eff}=\pi^{3/2}\omega_{xy}^2\omega_z .\, : D gives the diffusion coefficient: : \ D=\omega_{xy}^2/{4\tau_D}.
Anomalous diffusion If the diffusing particles are hindered by obstacles or pushed by a force (molecular motors, flow, etc.), the dynamics is often not sufficiently well-described by the normal
diffusion model, where the
mean squared displacement (MSD) grows linearly with time. Instead the diffusion may be better described as
anomalous diffusion, where the temporal dependence of the MSD is non-linear, as in the power-law: : \ MSD= 6 D_a t^\alpha \, where D_a is an anomalous diffusion coefficient. "Anomalous diffusion" commonly refers only to this very generic model, and not the many other possibilities that might be described as anomalous. Also, a power law is, in a strict sense, the expected form only for a narrow range of rigorously defined systems, for instance when the distribution of obstacles is
fractal. Nonetheless, a power law can be a useful approximation for a wider range of systems. The FCS autocorrelation function for anomalous diffusion is: : G(\tau)=G(0)\frac{1}{(1+(\tau/\tau_D)^\alpha)(1+a^{-2}(\tau/\tau_D)^\alpha)^{1/2}} +G(\infty), where the anomalous exponent \alpha is the same as above, and becomes a free parameter in the fitting. Using FCS, the anomalous exponent has been shown to be an indication of the degree of molecular crowding (it is less than one and smaller for greater degrees of crowding).
Polydisperse diffusion If there are diffusing particles with different sizes (diffusion coefficients), it is common to fit to a function that is the sum of single component forms: : \ G(\tau)=G(0)\sum_i \frac{\alpha_i}{(1+(\tau/\tau_{D,i}))(1+a^{-2}(\tau/\tau_{D,i}))^{1/2}} +G(\infty) where the sum is over the number different sizes of particle, indexed by i, and \alpha_i gives the weighting, which is related to the
quantum yield and concentration of each type. This introduces new parameters, which makes the fitting more difficult as a higher-dimensional space must be searched. Nonlinear least square fitting typically becomes unstable with even a small number of \tau_{D,i}s. A more robust fitting scheme, especially useful for polydisperse samples, is the Maximum Entropy Method.
Diffusion with flow With diffusion together with a uniform flow with velocity v in the lateral direction, the autocorrelation is: : \ G(\tau)=G(0)\frac{1}{(1+(\tau/\tau_{D}))(1+a^{-2}(\tau/\tau_{D}))^{1/2}} \times \exp[-(\tau/\tau_v)^2 \times \frac{1}{1+\tau/\tau_D}] +G(\infty) where \tau_v=\omega_{xy}/v is the average residence time if there is only a flow (no diffusion).
Chemical relaxation A wide range of possible FCS experiments involve chemical reactions that continually fluctuate from equilibrium because of thermal motions (and then "relax"). In contrast to diffusion, which is also a relaxation process, the fluctuations cause changes between states of different energies. One very simple system showing chemical relaxation would be a stationary binding site in the measurement volume, where particles only produce signal when bound (e.g. by FRET, or if the diffusion time is much faster than the sampling interval). In this case the autocorrelation is: : \ G(\tau)=G(0) \exp(-\tau/\tau_B) +G(\infty) where : \ \tau_B=(k_\text{on}+k_\text{off} )^{-1} is the relaxation time and depends on the reaction kinetics (on and off rates), and: : G(0) = \frac{1}{\langle N\rangle} \frac{k_{on}}{k_{off}} = \frac{1}{\langle N\rangle} K is related to the equilibrium constant
K. Most systems with chemical relaxation also show measurable diffusion as well, and the autocorrelation function will depend on the details of the system. If the diffusion and chemical reaction are decoupled, the combined autocorrelation is the product of the chemical and diffusive autocorrelations.
Triplet state correction The autocorrelations above assume that the fluctuations are not due to changes in the fluorescent properties of the particles. However, for the majority of (bio)organic fluorophores—e.g.
green fluorescent protein, rhodamine,
Cy3 and
Alexa Fluor dyes—some fraction of illuminated particles are excited to a
triplet state (or other non-radiative decaying states) and then do not emit
photons for a characteristic relaxation time \tau_F. Typically \tau_F is on the order of microseconds, which is usually smaller than the dynamics of interest (e.g. \tau_D) but large enough to be measured. A multiplicative term is added to the autocorrelation to account for the triplet state. For normal diffusion: : \ G(\tau)=G(0)\frac{(1-F+Fe^{-\tau/\tau_F})}{(1-F)}\frac{1}{(1+(\tau/\tau_{D,i}))(1+a^{-2}(\tau/\tau_{D,i}))^{1/2}}+G(\infty) where \ F is the fraction of particles that have entered the triplet state and \ \tau_F is the corresponding triplet state relaxation time. If the dynamics of interest are much slower than the triplet state relaxation, the short time component of the autocorrelation can simply be truncated and the triplet term is unnecessary. ==Common fluorescent probes==