Techniques and systems are disclosed for locomoting fuel-free nanomotors in a fluid. In one aspect of the disclosed technology, a system for locomoting fuel-free nanomotors can include an electrically-driven nanowire diode formed of two or more segments of different electrically conducting materials, a fluid container, and a mechanism that produces an electric field to drive the nanowire diode to locomote in the fluid. In another aspect, a system for locomoting fuel-free nanomotors can include a magnetically-propelled multi-segment nanowire motor formed of a magnetic segment and a flexible joint segment, a fluid container, and a mechanism that generates and controls a magnetic field to drive the multi-segment nanowire motor to locomote in the fluid. The disclosed fuel-free nanomotors can obviate fuel requirements and can be implemented for practical in vitro and in vivo biomedical applications.

Nanoelectromechanical (NEMS) devices having nanomagnets for an improved range of operating voltages and improved control of dimensions of a cantilever are described. For example, in an embodiment, a nanoelectromechanical (NEMS) device includes a substrate layer, a first magnetic layer disposed above the substrate layer, a first dielectric layer disposed above the first magnetic layer, a second dielectric disposed above the first dielectric layer, and a cantilever disposed above the second dielectric layer. The cantilever bends from a first position to a second position towards the substrate layer when a voltage is applied to the cantilever.

An apparatus includes a body having walls defining a cavity therebetween, the cavity containing an amount of a subject material therein. A channel structure including a channel substrate with channels having a substantially uniform width formed therein is disposed along a portion of the walls of the body, and a liner material is disposed over portions of internal surfaces of the channels.

Aspects of the present disclosure generally relate to vibration sensors. The vibration sensors can include a vibration sensor including at least an aperture. A polymer including a n elastomer is disposed on the frame. A nanoribbon network is disposed on the polymer. Two or more electrodes are disposed on the nanoribbon network. The two or more electrodes have a spacing of about 500 nm to about 2000 m.

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.