Abstract: A method for dielectrophoresis includes applying an electric field across a micro-fluidic chamber with an alternating current (AC), trapping the target particles on the at least one carrier particle, transporting the target particles from a first location in the chamber to a second location in the chamber distanced from the first location with the at least one carrier particle and dynamically controlling the trapping and the transporting based on remotely applying forces on the at least one carrier particle. The trapping is based on localized gradients of the electric field induced by the carrier particle. The applied electric field is uniform absent a carrier particle present in the micro-fluidic chamber. The micro-fluidic chamber contains an electrolyte-solution with suspended target particles and at least one carrier particle freely floating on or in the electrolyte-solution.

Abstract: A method for dielectrophoresis includes applying an electric field across a micro-fluidic chamber with an alternating current (AC), trapping the target particles on the at least one carrier particle, transporting the target particles from a first location in the chamber to a second location in the chamber distanced from the first location with the at least one carrier particle and dynamically controlling the trapping and the transporting based on remotely applying forces on the at least one carrier particle. The trapping is based on localized gradients of the electric field induced by the carrier particle. The applied electric field is uniform absent a carrier particle present in the micro-fluidic chamber. The micro-fluidic chamber contains an electrolyte-solution with suspended target particles and at least one carrier particle freely floating on or in the electrolyte-solution.