A magnetic-hydrodynamic force fluid logic controller is provide that includes a solid or flexible or flexible substrate, a fluid chamber disposed above the substrate, where the chamber includes a fluid under test that includes an active magnet, where the active magnet is disposed to control a magnetic north pole of the droplet and a magnetic south pole of the droplet, a two-dimensional distribution of magnetic elements a surface the solid or flexible substrate, where the magnetic elements comprise a magnetization in a magnetic north pole and magnetization in a magnetic south pole, where the magnetic elements are activated by an external magnetic field of the active magnet, where the droplets have a droplet magnetization, where the droplet magnetization is configured for droplet self-interaction by the magnetic elements and the active magnet, where the self-interaction comprises splitting, merging, propagation, logic, storage, memory and all possible combinations of logical circuit operations.

A magnetohydrodynamic microfluidic system and a method of pumping a fluid using a magnetohydrodynamic system are disclosed. The method includes applying at least one of an electric current and an electric voltage to a first modified electrode and a second electrode to generate an ionic current between the first modified electrode and the second electrode and to cause a current carrying species to move to or from the modified electrode, applying a magnetic field perpendicular to an ionic current vector, the magnetic field and the ionic current combining to induce flow of the fluid in a direction perpendicular to the magnetic field and the ionic current vector, and maintaining fluid flow by recharging the modified electrode.

An active microfluidic droplet generation device includes a droplet generation junction joining at least one continuous phase channel for carrying a ferrofluid, and a dispersed phase channel for carrying a dispersed phase (e.g., aqueous) flow. A miniature electropermanent magnet (EPM) upstream from the junction generates a magnetic field to modulate a flow rate of a ferrofluid in the continuous phase channel so that dispersed phase droplets are generated with volumes actively controlled on-demand and under continuous flow.

A magnetic-hydrodynamic force fluid logic controller is provide that includes a solid or flexible or flexible substrate, a fluid chamber disposed above the substrate, where the chamber includes a fluid under test that includes an active magnet, where the active magnet is disposed to control a magnetic north pole of the droplet and a magnetic south pole of the droplet, a two-dimensional distribution of magnetic elements a surface the solid or flexible substrate, where the magnetic elements comprise a magnetization in a magnetic north pole and magnetization in a magnetic south pole, where the magnetic elements are activated by an external magnetic field of the active magnet, where the droplets have a droplet magnetization, where the droplet magnetization is configured for droplet self-interaction by the magnetic elements and the active magnet, where the self-interaction comprises splitting, merging, propagation, logic, storage, memory and all possible combinations of logical circuit operations.

A temperature regulation system for samples in a microplate includes a housing defining an interior volume and first and second airflow ports defined by a first and second exterior surfaces of the housing. The system includes an electromagnetic mixing system that has a base plate defining a plurality of openings, and a plurality of electromagnets. Each electromagnet defines an axis that extends substantially vertically from the base plate. The base plate is disposed in the interior volume and each of the plurality of electromagnets extend toward the first airflow port. A fan is disposed in the interior volume substantially below the base plate. Activation of the fan draws air into the first or second airflow port, substantially parallel to each axis of the plurality of electromagnets, through the plurality of openings, and out of the other of the second and first airflow port.

A temperature regulation system for samples in a microplate includes a housing defining an interior volume and first and second airflow ports defined by a first and second exterior surfaces of the housing. The system includes an electromagnetic mixing system that has a base plate defining a plurality of openings, and a plurality of electromagnets. Each electromagnet defines an axis that extends substantially vertically from the base plate. The base plate is disposed in the interior volume and each of the plurality of electromagnets extend toward the first airflow port. A fan is disposed in the interior volume substantially below the base plate. Activation of the fan draws air into the first or second airflow port, substantially parallel to each axis of the plurality of electromagnets, through the plurality of openings, and out of the other of the second and first airflow port.