Direct Observation of Polymer Network Structure in Macroporous N-Isopropylacrylamide Gel by Raman Microscopy

Abstract

The Raman microscopy technique is used to characterize the temperature-induced evolution of the pore structures of a macroporous N-isopropylacrylamide (NIPA). The gel is synthesized using a suspension of 45 wt % toluene and 55 wt % pregel NIPA solution. The intensity of the band due to the CH₂ bending vibration, centered at 1445 cm^-1, is used to monitor the distribution of the polymer chain density in the lateral plane. It is found that the macroporous gel consists of water-rich areas, which can be interpreted as the pores, and polymer-rich areas. At room temperature, the average sizes of the pores and the width of polymer-rich areas are 75 μm and 20 μm, respectively. Both the pores and their surrounding polymer-rich areas have random geometry, as demonstrated by the Raman microimaging. With increased temperature the size of the pores decreases. This process is accompanied by a narrowing of the polymer-rich areas. At higher temperatures polymer chains bunch together and this process accelerates rapidly near the volume phase transition temperature (34 °C). Above 36 °C, the pore sizes become too small to be resolved using Raman microscopy.