Written by Michael Sakillaris, Shipley Corporation, Northborough MA
The bulk properties of polymer solutions are sensitive to polymer concentration. Polymer solutions are typically described as being either dilute, semi-dilute, or concentrated. The concentration defining the border between the dilute and semi-dilute regions is defined as C*, and is representative of the concentration at which polymer chain entanglement is first observed.
Bulk viscosity is a property that can be used to establish C*. Within the dilute concentration regime, an increase in polymer concentration leads to a linear increase in the bulk viscosity. When chain entanglement occurs, the bulk viscosity deviates from linearity, due to the added visco-elastic effects of chain slippage and polymer interactions. Consider Figure 1 for example, which shows the concentration dependence of the bulk viscosity for a low molecular weight polymer (trade name Synapse) in an organic solvent, and indicates a C* value of ~ 50 mg/ml.
In its simplest form, the scattering intensity of a polymer solution can be described as being proportional to the concentration and the square of the molecular weight. For a constant molecular weight polymer then, the scattering intensity should increase proportionally with the increase in sample concentration. For polymer solutions in the dilute region, a linear concentration dependence is the norm. Within the semi-dilute region however, multiple scattering reduces the number of photons arriving at the detector at higher concentrations, resulting in a decrease in scattering intensity with increasing concentration. The effects of multiple scattering are evident in Figure 2, which shows the concentration dependence of the scattering intensity and the bulk viscosity for the Synapse polymer, and indicates a peak in the sample scattering intensity that is consistent with C*.
The size distributions for the Synapse polymer are shown in Figure 3, which indicates non-aggregated mono-disperse distributions (~ 5.5 nm diameter) for all sample concentrations.
The concentration dependence of the scattering intensity in the dilute regime can also be used to measure the molecular weight of the polymer. The Rayleigh ratio (Rθ) is the ratio of the sample to incident scattering intensities. For particles smaller than 100 nm diameter, the concentration dependence of the Rayleigh ratio can be described as given below, where K is an optical constant, C is the analyte concentration, M is the weight average molecular weight, and A2 is the 2nd virial coefficient (representative of the magnitude of particle - solvent interactions).
The Rayleigh expression given above is represented graphically in the form of a Debye plot showing the concentration dependence of KC/Rθ. The Debye plot for the Synapse data is shown in Figure 4, which indicates a molecular weight of 18.55 kDa and a 2nd virial coefficient of 0.001878 ml mol / g2.
The measured 18.55 kDa molecular weight of Synapse is consistent with size exclusion chromatography results, which give an estimated weight average molecular weight of 20 kDa. The positive value of the 2nd virial coefficient indicates that solvation is more energetically favorable than polymer aggregation, and suggests a high solubility limit in the organic solvent used in this study.
The size and mass measurements for the Synapse samples used in this study were collected using a Malvern Panalytical Zetasizer Nano ZS system.