A magnetically controllable robotic device including a body having a first body part and a second body part movably connected with the first body part. The first body part and the second body part are both rigid. The first body part is magnetically-responsive such that the first body part can be controlled by an external magnetic field generated by an magnetic control system. The first body part may be controlled such that the magnetically controllable robotic device is moved by the external magnetic field.

The present disclosure relates to a dual hybrid electromagnet module for controlling a microrobot. More specifically, the present disclosure relates to an electromagnetic field system in which a dual hybrid electromagnet module including a permanent magnet and an electromagnet is used for controlling a microrobot so that it is possible to reduce the number of used electromagnets so as to reduce power consumption and the amount of heat generated from the electromagnet module. The electromagnetic field system is capable of being used for various medical procedures and surgeries using a microrobot.

The present disclosure relates to a dual hybrid electromagnet module for controlling a microrobot. More specifically, the present disclosure relates to an electromagnetic field system in which a dual hybrid electromagnet module including a permanent magnet and an electromagnet is used for controlling a microrobot so that it is possible to reduce the number of used electromagnets so as to reduce power consumption and the amount of heat generated from the electromagnet module. The electromagnetic field system is capable of being used for various medical procedures and surgeries using a microrobot.

A three-dimensional (3D) untethered mobile actuator having the following parts: (a) a substrate having two or more magnetized panels, and (b) a frame that connects the magnetized panels, the magnetized panels being made of a polymer with embedded permanent magnetic particles, each magnetized panel of the 3D untethered mobile actuator having a magnetic moment in a different direction than a next neighboring panel, and the 3D untethered mobile actuator having a structural configuration that changes between a substantially flat structural configuration in the absence of a magnetic field, and an actuated structural configuration when under influence of a magnetic field. Methods of manufacturing and using the 3D mobile actuator and a system that includes the 3D mobile actuator are provided.

A three-dimensional (3D) untethered mobile actuator having the following parts: (a) a substrate having two or more magnetized panels, and (b) a frame that connects the magnetized panels, the magnetized panels being made of a polymer with embedded permanent magnetic particles, each magnetized panel of the 3D untethered mobile actuator having a magnetic moment in a different direction than a next neighboring panel, and the 3D untethered mobile actuator having a structural configuration that changes between a substantially flat structural configuration in the absence of a magnetic field, and an actuated structural configuration when under influence of a magnetic field. Methods of manufacturing and using the 3D mobile actuator and a system that includes the 3D mobile actuator are provided.

Provided herein are manipulators for handling fragile layers and related methods of handling using the manipulators. The manipulators comprise a contact surface with thermally responsive recess features and a microelectric heater in thermal contact with the contact surface. In this manner, the manipulator is an electrothermal manipulator, with changes in temperature providing a contact force to pick-up a transferable layer material and a release force to facilitate release of the transferable from the manipulator.

Provided herein are manipulators for handling fragile layers and related methods of handling using the manipulators. The manipulators comprise a contact surface with thermally responsive recess features and a microelectric heater in thermal contact with the contact surface. In this manner, the manipulator is an electrothermal manipulator, with changes in temperature providing a contact force to pick-up a transferable layer material and a release force to facilitate release of the transferable from the manipulator.

A microrobot is disclosed. The microrobot includes a magnet configured to provide a motive force when magnetic force of one or more electrical coils act upon the magnet, a support member coupled to the magnet, a thermo-responsive polymer member coupled to each end of the support member at a proximal end, the thermo-responsive polymer member configured to articulate when heated, wherein the thermo-responsive polymer members configured to receive light from a microrobot structured light system and convert the received light into heat.

A microrobot is disclosed. The microrobot includes a magnet configured to provide a motive force when magnetic force of one or more electrical coils act upon the magnet, a support member coupled to the magnet, a thermo-responsive polymer member coupled to each end of the support member at a proximal end, the thermo-responsive polymer member configured to articulate when heated, wherein the thermo-responsive polymer members configured to receive light from a microrobot structured light system and convert the received light into heat.

Time multiplexing an electromagnetic trap beam may be used to generate trap shapes/geometries to trap one or more particles with one electromagnetic beam by directing the electromagnetic beam at a pattern of different locations with sufficient rapidity to form an effective shape/geometry. Additionally, multiplexing an electromagnetic trap beam may be used to shutter trapping electromagnetic radiation to protect a viewer, use the same beam for multiple functions, move and organize particles, and generate illumination effects.