Conjugation Length-Dependent Raman Scattering Intensity of Conjugated Polymers

Polydiacetylenes, as a class of conjugated polymers with alternating conjugated CC and C & EQUIV;C bonds, have emerged as a promising probe material for biomedical Raman imaging, given their ultrastrong Raman scattering intensity. However, the relationship between the structure, especially the molecular length of polydiacetylenes, and their Raman scattering intensity remains unclear. In this work, a series of water-soluble polydiacetylenes, namely poly(deca-4,6-diynedioic acid) (PDDA) with different molecular weights (MWs), is prepared through controlled polymerization and degradation. The ultraviolet-visible (UV-vis) absorption spectroscopic and Raman spectroscopic studies on these polymers reveal that the Raman scattering intensity of PDDA increases nonlinearly with the MW. The MW-Raman scattering intensity relationship in the polymerization process is completely different from that in the degradation process. In contrast, the Raman scattering intensity increases more linearly with the maximal absorbance of the polymer, and the relationship between the Raman scattering intensity and the maximal absorbance of PDDA in the polymerization process is consistent with that in the degradation process. The Raman scattering intensity of PDDA hence exhibits a better dependence on the effective conjugation length of the polymer, which should guide the future design of conjugated polymers for Raman imaging applications. The structure-Raman activity relationship of the conjugated polymers is crucial for developing ideal Raman probes. Based on a series of water-soluble polydiacetylenes (poly(deca-4,6-diynedioic acid), PDDA) with different molecular weights (MWs) through controlled polymerization and degradation, the conjugation length dependence of polydiacetylene Raman signal is revealed, which will guide the future design of conjugated polymers for Raman imaging applications.image