Deformation Rate‐Adaptive Conducting Polymers and Composites

Abstract: Materials are more easily damaged during accidents that involve rapid deformation. Here, a design strategy is described for electronic materials comprised of conducting polymers that defies this orthodox property, making their extensibility and toughness dynamically adaptive to deformation rates. This counterintuitive property is achieved through a morphology of interconnected nanoscopic core–shell micelles, where the chemical interactions are stronger within the shells than the cores. As a result, the interli… Show more

“…3–7 In view of this, SCs can be employed in various potential applications such as portable electronics, digital telecommunication systems, biomedical implants and wearable devices. 8–12 Up to now, although many efforts have been devoted to the fabrication of SCs, final electrochemical performances are limited by low energy density and weak specific capacitances. 13,14 Moreover, the preparation of high-performance SCs could also be influenced by other factors, including structure morphology, size, stability, active sites and conductivity of electrode materials.…”

Efficient improvement in the electrochemical performance of petal-like lamellar NiMn–LDHs with affluent oxygen vacancies derived from Mn MOF-74

“…3–7 In view of this, SCs can be employed in various potential applications such as portable electronics, digital telecommunication systems, biomedical implants and wearable devices. 8–12 Up to now, although many efforts have been devoted to the fabrication of SCs, final electrochemical performances are limited by low energy density and weak specific capacitances. 13,14 Moreover, the preparation of high-performance SCs could also be influenced by other factors, including structure morphology, size, stability, active sites and conductivity of electrode materials.…”

Efficient improvement in the electrochemical performance of petal-like lamellar NiMn–LDHs with affluent oxygen vacancies derived from Mn MOF-74

“…However, a major challenge in developing tissue engineering scaffolds for myocardial repair is the structural and mechanical mismatch with native myocardial tissue [ 11 ]. The myocardium, possessing the negative Poisson's ratio property, expands transversely under longitudinal stretching, a feature crucial for enduring the load of daily activities [ [12] , [13] , [14] ]. Lacking this characteristic, the transplantation of most traditional scaffolds may potentially lead to loss of cell vitality and function, thereby diminishing the scaffold's efficacy [ 15 ].…”

Composite patch with negative Poisson's ratio mimicking cardiac mechanical properties: Design, experiment and simulation