Conductive elastic composites have been used widely in soft electronics and soft robotics. These composites are typically a mixture of conductive fillers within elastomeric substrates. They can sense strain via changes in resistance resulting from separation of the fillers during elongation. Thus, most elastic composites exhibit a negative piezoconductive effect, i.e. the conductivity decreases under tensile strain. This property is undesirable for stretchable conductors since such composites may become less conductive during deformation. Here, we report a liquid metal-filled magnetorheological elastomer comprising a hybrid of fillers of liquid metal microdroplets and metallic magnetic microparticles. The composite’s resistivity reaches a maximum value in the relaxed state and drops drastically under any deformation, indicating that the composite exhibits an unconventional positive piezoconductive effect. We further investigate the magnetic field-responsive thermal properties of the composite and demonstrate several proof-of-concept applications. This composite has prospective applications in sensors, stretchable conductors, and responsive thermal interfaces.
We report an anisotropic conductive elastomer consisting of liquid metal microdroplets and magnetically aligned ferromagnetic microparticles within a silicone matrix. This composite exhibits both piezoconductive and piezoresistive effects within the same sample, depending on the direction of measurement relative to the direction of particle alignment. We harness these unique properties to demonstrate soft tactile logic devices and a range-adjustable rheostat. This work has the potential to advance the development of soft tactile sensors and flexible electronics.
Microfluidic systems enable rapid diagnosis of diseases, biological analysis, drug screening, and high-precision materials synthesis. In spite of these remarkable abilities, conventional microfluidic systems are microfabricated monolithically on a single platform and their operations rely on bulky expensive external equipment. This restricts their applications outside of research laboratories, and prevents development and assembly of truly versatile and complex systems. Here, we present novel magnetorheological elastomer (MRE) microactuators including pumps and mixers using an innovative actuation mechanism without the need of delicate elements such as thin membranes. Modularized elements are realized using such actuators, which can be easily integrated and actuated using a single self-contained driving unit to create a modular, miniaturized, and robust platform. We investigate the performance of the microactuators via a series of experiments, and develop a proof-of-concept modular system to demonstrate the viability of the platform for self-contained applications. The presented MRE microactuators are small size, simple, and efficient, offering a great potential to significantly advance the current research on complex microfluidic systems.
A variable resonance magnetorheological-fluid-based pendulum tuned mass A variable resonance magnetorheological-fluid-based pendulum tuned mass damper for seismic vibration suppression damper for seismic vibration suppression
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