Disclosed herein are oligomeric machines comprising a first oligomeric module having a first end and a second end, and a second oligomeric module having a first end and a second end; wherein the first end of the first oligomeric module is joined to the first end of the second oligomeric module; and wherein the oligomeric machine exhibits stochastic resonance and/or spontaneous vibrations in a solution at a temperature when the temperature is in a critical temperature range and the oligomeric machine does not exhibit stochastic resonance in the solution when the temperature is not in the critical temperature range; and the oligomeric machine exhibits stochastic resonance and/or spontaneous vibrations in a solution under a force load applied to the oligomeric machine when the force load is in a critical force range and the oligomeric machine does not exhibit stochastic resonance and/or spontaneous vibrations in the solution when the force load is not in the critical range. Also disclosed herein are molecular sensors comprising an oligomeric machine and configured to bind with one or more analytes thus modulating the stochastic resonance and/or spontaneous vibrations of the oligomeric machine. Additionally disclosed are uses of molecular sensors for the detection of one or more analytes in a solution.

A lighting device is provided, including: a substrate having a first surface and a second surface opposite the first surface; one or more light-emitting structures formed on the first surface of the substrate; and a heat spreading and dissipating layer formed on the second surface of the substrate, wherein the heat spreading and dissipating layer comprises a polymer layer mixed with nano graphite particles.

This present disclosure provides methods for utilizing such forces in when generating nanofibrillar constructs with engineered morphology from the nano- to macro-scales. Using for example, a biopolymer silk fibroin as a base material, patterns an intermediate hydrogel were generated within a deformable mold. Subsequently, mechanical tension was introduced via either hydrogel contraction or mold deformation, and finally a material is reentrapped in this transformed shape via beta-sheet crystallization and critical point drying. Topdown engineered anchorages, cables, and shapes act in concert to mediate precision changes in nanofiber alignment/orientation and a macroscale form of provided nanofibrillar structure. An ability of this technique to engineer large gradients of nano- and micro-scale order, manipulate mechanical properties (such as plasticity and thermal transport), and the in-situ generation of 2D and 3D, multi-tiered and doped, nanofibrillar constructs was demonstrated.

A molecular machine comprising a movement part (2) including a first molecular element (4), a second molecular element (5), and a linking element (6) for constraining a relative movement of the first molecular element (4) and the second molecular element (5), and a control part configured to generate an electrical field around the movement part (2), wherein the first molecular element (4) is fixed relative to the control part, wherein the second molecular element (5) is movable relative to the first molecular element (4) in at least one degree of freedom, and wherein the second molecular element (5) is electrically charged such that the second molecular element (5) aligns to said electrical field.

A method for manufacturing an electromechanical actuator includes providing a primary stack of layers comprising a monocrystalline layer, providing a secondary stack of layers, and forming, in the etching layer, at least three pads. The method further includes encapsulating the three pads by a first encapsulation layer, assembling the primary stack of layers with the secondary stack of layers, removing the first substrate, and forming a movable electrode in the monocrystalline layer.

This invention provides electromechanical resonators based on metal chalcogenide nanotubes. The invention further provides methods of fabrication of electromechanical resonators and methods of use of such electromechanical resonators.

A method for manufacturing an electromechanical actuator includes providing a primary stack of layers comprising a monocrystalline layer, providing a secondary stack of layers, and forming, in the etching layer, at least three pads. The method further includes encapsulating the three pads by a first encapsulation layer, assembling the primary stack of layers with the secondary stack of layers, removing the first substrate, and forming a movable electrode in the monocrystalline layer.

Disclosed are devices, systems, and methods for fabrication of moving, actuatable structures at micron scales that can be electronically controlled using low power and low voltages. Also disclosed are microscale robots having such microscale actuator structures to actuate the robots’ movements as well as devices, systems, and methods for fabrication of microscale robots. The disclosed methods of fabrication are compatible with standard semiconductor technologies.

This invention provides electromechanical resonators based on metal chalcogenide nanotubes. The invention further provides methods of fabrication of electromechanical resonators and methods of use of such electromechanical resonators.

This invention provides electromechanical resonators based on metal chalcogenide nanotubes. The invention further provides methods of fabrication of electromechanical resonators and methods of use of such electromechanical resonators.