Bridging pico-to-nanonewtons with a ratiometric force probe for monitoring nanoscale polymer physics before damage

Understanding the transmission of nanoscale forces is important in polymer physics but physical approaches have limitations in analyzing the local force distribution in condensed environments. Here, the authors report a conformation flexible dual-fluorescent force probe and realize ratiometric analysis of the distribution of local forces in a stretched polymer chain network. Understanding the transmission of nanoscale forces in the pico-to-nanonewton range is important in polymer physics. While physical approaches have limitations in analyzing the local force distribution in condensed environments, chemical analysis using force probes is promising. However, there are stringent requirements for probing the local forces generated before structural damage. The magnitude of those forces corresponds to the range below covalent bond scission (from 200 pN to several nN) and above thermal fluctuation (several pN). Here, we report a conformationally flexible dual-fluorescence force probe with a theoretically estimated threshold of approximately 100 pN. This probe enables ratiometric analysis of the distribution of local forces in a stretched polymer chain network. Without changing the intrinsic properties of the polymer, the force distribution was reversibly monitored in real time. Chemical control of the probe location demonstrated that the local stress concentration is twice as biased at crosslinkers than at main chains, particularly in a strain-hardening region. Due to the high sensitivity, the percentage of the stressed force probes was estimated to be more than 1000 times higher than the activation rate of a conventional mechanophore.

Automated summary

Understanding the transmission of nanoscale forces is crucial in polymer physics. Physical approaches have limitations in analyzing the local force distribution in condensed environments. This study presents a conformationally flexible dual-fluorescence force probe, enabling ratiometric analysis of the distribution of local forces in a stretched polymer chain network. Chemical control of the probe location reveals a higher local stress concentration at crosslinkers than at main chains, especially in a strain-hardening region.