The changes in the redox behavior and nanoscale morphology of poly[2,2'-bithiophene] deposited onto highly oriented pyrolytic graphite substrates upon repeated doping-undoping were studied. It was shown that repeated cycling resulted in very particular changes in the voltammetric response of the polymer films as well as their nanoscale morphology. Specifically, when the cycling was performed to relatively low anodic potentials, the overall doping-undoping charge did not change; however, the shape of voltammograms was consistently changing showing broadening of the voltammograms and reducing of the doping peak height in the anodic scan, as well as broadening and deterioration of the undoping peak in the reverse scan. Furthermore, a remarkable feature was observed that all voltammogram traces intersected at several characteristic potentials producing quasi-isosbestic points. With an increase in the anodic scan potential limit, the overall doping-undoping charge starts to decrease showing irreversible degradation of the polymer; however, the general pattern of the peak broadening could be still observed. Atomic force microscopic (AFM) studies of the polymer films cycled to various anodic limits showed that repeated cycling resulted in a gradual decrease in the degree of crystallinity, as revealed by AFM phase imaging, and an increase in the degree of disorder. Coupled with the changes in the redox behavior, these findings suggested the formation of more flexible and open polymer nanostructure that enables easier penetration of the dopant ions and solvent. However, at the same time, an increase in the degree of disorder reduced the interchain interactions and inhibited the formation of extended electronic states delocalized across neighboring polymer chains. This occurred at first without irreversible degradation of the polymer and a decrease in the overall doping-undoping charge. Cycling to higher anodic potentials resulted in irreversible degradation accompanied by profound changes in the polymer morphology. (c) 2012 Elsevier Ltd. All rights reserved.