Single-molecule tracking of dye diffusion in synthetic polymers: A tutorial review

Abstract

Single-molecule tracking (SMT) methods have been widely employed to offer a high-resolution characterization of synthetic polymers under ambient conditions and, thus, have advanced our understanding of their unique material properties. SMT is based on the systematic monitoring of the diffusive motions of individual fluorescent dye molecules in the as-prepared polymer thin films or thicker monoliths. Quantitative assessment of the recorded SMT video data involves the systematic analysis of the generated diffusion trajectories of a single molecule using well-established and reported methods. The results have offered a wealth of new information on the structural alignment, orientational order, and long-range continuity of the polymer microdomains; the nanoscale material heterogeneities governed by defects, misalignment, and ill-controlled preparation conditions; as well as the various forms of probe–host interactions on the single-molecule level. In the first part of this Tutorial review, we describe the fundamental principles and instrumentation of SMT, before offering interested readers and potential future SMT users a practical guidance on the selection of fluorescent probe molecules, preparation of suitable samples, and optimization of experimental conditions and imaging parameters. Then, we highlight several representative SMT studies in microphase-separated block copolymers, and semicrystalline and amorphous homopolymers to further emphasize the usefulness of SMT methods for polymer characterization without neglecting some of their shortcomings. This Tutorial review is written with the motivation to attract new researchers to the fast-growing field and assist them in starting their own SMT research of synthetic polymers and other technologically useful soft matter systems.