Polymer semiconductors (PSCs) are an essential component of organic field‐effect transistors (OFETs), but their potential for stretchable electronics is limited by their brittleness and failure susceptibility upon strain. Herein, a covalent connection of two state‐of‐the‐art polymers—semiconducting poly‐diketo‐pyrrolopyrrole‐thienothiophene (PDPP‐TT) and elastomeric poly(dimethylsiloxane) (PDMS)—in a single triblock copolymer (TBC) chain is reported, which enables high charge carrier mobility and low modulus in one system. Three TBCs containing up to 65 wt% PDMS were obtained, and the TBC with 65 wt% PDMS content exhibits mobilities up to 0.1 cm2 V−1 s−1, in the range of the fully conjugated reference polymer PDPP‐TT (0.7 cm2 V−1 s−1). The TBC is ultrasoft with a low elastic modulus (5 MPa) in the range of mammalian tissue. The TBC exhibits an excellent stretchability and extraordinary durability, fully maintaining the initial electric conductivity in a doped state after 1500 cycles to 50% strain.
In the midst of the COVID-19 pandemic, adaptive solutions are needed to allow us to make fast decisions and take effective sanitation measures, e.g., the fast screening of large groups (employees, passengers, pupils, etc.). Although being reliable, most of the existing SARS-CoV-2 detection methods cannot be integrated into garments to be used on demand. Here, we report an organic field-effect transistor (OFET)-based biosensing device detecting of both SARS-CoV-2 antigens and anti-SARS-CoV-2 antibodies in less than 20 min. The biosensor was produced by functionalizing an intrinsically stretchable and semiconducting triblock copolymer (TBC) film either with the anti-S1 protein antibodies (S1 Abs) or receptor-binding domain (RBD) of the S1 protein, targeting CoV-2-specific RBDs and anti-S1 Abs, respectively. The obtained sensing platform is easy to realize due to the straightforward fabrication of the TBC film and the utilization of the reliable physical adsorption technique for the molecular immobilization. The device demonstrates a high sensitivity of about 19%/dec and a limit of detection (LOD) of 0.36 fg/mL for anti-SARS-Cov-2 antibodies and, at the same time, a sensitivity of 32%/dec and a LOD of 76.61 pg/mL for the virus antigen detection. The TBC used as active layer is soft, has a low modulus of 24 MPa, and can be stretched up to 90% with no crack formation of the film. The TBC is compatible with roll-to-roll printing, potentially enabling the fabrication of low-cost wearable or on-skin diagnostic platforms aiming at point-of-care concepts.
Polymer brushes,
consisting of densely end-tethered polymers to
a surface, can exhibit rapid and sharp conformational transitions
due to specific stimuli, which offer intriguing possibilities for
surface-based sensing of the stimuli. The key toward unlocking these
possibilities is the development of methods to readily transduce signals
from polymer conformational changes. Herein, we report on single-fluorophore
integrated ultrathin (<40 nm) polymer brush surfaces that exhibit
changing fluorescence properties based on polymer conformation. The
basis of our methods is the change in occupied volume as the polymer
brush undergoes a collapse transition, which enhances the effective
concentration and aggregation of the integrated fluorophores, leading
to a self-quenching of the fluorophores’ fluorescence and thereby
reduced fluorescence lifetimes. By using fluorescence lifetime imaging
microscopy, we reveal spatial details on polymer brush conformational
transitions across complex interfaces, including at the air–water–solid
interface and at the interface of immiscible liquids that solvate
the surface. Furthermore, our method identifies the swelling of polymer
brushes from outside of a direct droplet (i.e., the
polymer phase with vapor above), which is controlled by humidity.
These solvation-sensitive surfaces offer a strong potential for surface-based
sensing of stimuli-induced phase transitions of polymer brushes with
spatially resolved output in high resolution.
Mechanical‐strain‐gated switches are cornerstone components of material‐embedded circuits that perform logic operations without using conventional electronics. This technology requires a single material system to exhibit three distinct functionalities: strain‐invariant conductivity and an increase or decrease of conductivity upon mechanical deformation. Herein, mechanical‐strain‐gated electric switches based on a thin‐film architecture that features an insulator‐to‐conductor transition when mechanically stretched are demonstrated. The conductivity changes by nine orders of magnitude over a wide range of tunable working strains (as high as 130%). The approach relies on a nanometer‐scale sandwiched bilayer Au thin film with an ultrathin poly(dimethylsiloxane) elastomeric barrier layer; applied strain alters the electron tunneling currents through the barrier. Mechanical‐force‐controlled electric logic circuits are achieved by realizing strain‐controlled basic (AND and OR) and universal (NAND and NOR) logic gates in a single system. The proposed material system can be used to fabricate material‐embedded logics of arbitrary complexity for a wide range of applications including soft robotics, wearable/implantable electronics, human–machine interfaces, and Internet of Things.
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