Devices, systems, and methods for applying a dielectrophoretic force on a particle include: a cell defining at least one channel for confining the particle; and a first electrode and a second electrode electrically isolated from the first electrode, at least one of the first and second electrodes being formed from a two-dimensional (2D) material providing an atomically sharp edge. The first and second electrodes are arranged sufficiently close to one another and sufficiently close to the channel such that application of a sufficient voltage across the first and second electrodes generates an electric field in at least part of the channel, the electric field having an electric field gradient sufficient to apply the dielectrophoretic force on the particle in the channel.

An apparatus and method for isolating bacterial particles in a sample using a container with material in temporary fluid blocking position to lower orifice in the container, a separation medium having an electrical conductivity lower than and physical density greater than that of the sample above the material that supports a sample concentrate after passing through the separation medium when exposed to centrifugal force, a heating element for liquefying the material to permit flow into a chamber past an electrode array that attracts and holds subject particles. The system allows rapid detection and isolation of particles from samples from animal, human, environmental sites, a bio-industrial reactor or a food or beverage production facility requiring relatively small volumes, short incubation times resulting in structurally intact particles for further analysis. Testing may be completed in a single unit that requires decreased technician manipulation, fewer steps and a decrease in cross-contamination.

Devices and methods for performing dielectrophoresis are described. The devices contain sample channel which is separated by physical barriers from electrode channels which receive electrodes. The devices and methods may be used for the separation and analysis of particles in solution, including the separation and isolation of cells of a specific type. As the electrodes do not make contact with the sample, electrode fouling is avoided and sample integrity is better maintained.

A dielectrophoretic detection device including a chip, with a flow channel having at least one inlet and one outlet, and at least a detection area configured to detect analytes trapped on functionalised beads flowing within the flow channel, first and second electrode assemblies shaped as rows of parallel pillars extending a the height of the flow channel, and configured to generate under electric tension an electric field to form an electrical barrier, and preventing the beads to cross the barrier and drawing the beads to the detection area by dielectrophoretic forces where they are clustered and concentrated. The device may be provided with multiple rows of parallel pillars of electrode assemblies extending over the height of the flow channel, forming multiple concentration lines. The flow channel may be provided with further rows of parallel pillars of electrode assemblies crossing the flow channel in a transverse direction, forming further incubation lines.

Devices and methods for capturing biological materials using a potential well. An electrical signal is applied across a nanopipette having one end in a back-fill chamber and another end in a collection chamber containing a suspending medium including one or more types of particles. The collection end of the nanopipette includes a tip having an opening. The electrical signal applied across the nanopipette is configured to generate the potential well proximate to the tip in which the electrokinetic forces acting on the particles are balanced. The potential well may be configured to selectively trap one or the other types of particles suspended in the suspending medium. The particles may be transferred to a sample collection medium by immersing the tip in the sample collection medium and reversing the polarity of the electrical signal.

A nanocarbon separation device includes a first porous structure configured to hold a solution containing a surfactant, a second porous structure configured to hold a dispersion medium, a holding part provided between the first porous structure and the second porous structure and configured to hold the dispersion liquid containing the nanocarbons and the surfactant and having a smaller content of the surfactant than that of the solution, a separation tank in which the first porous structure, the holding part and the second porous structure are disposed and accommodated in an order of the first porous structure, the holding part and the second porous structure, a first electrode provided on a lower section of the first porous structure, and a second electrode provided on an upper section of the second porous structure.

A contactless selection device, a light triggering structure thereof, and a biological particle selection apparatus are provided. The light triggering structure includes a first substrate, a first electrode layer formed on the first substrate, a photodiode layer formed on the first electrode layer, and an insulating layer that covers the photodiode layer. The photodiode layer has a thickness within a range from 1 .Math.m to 3 .Math.m, and includes a first doped layer, an I-type layer, and a second doped layer, which are sequentially stacked from the first electrode layer. The second doped layer includes a plurality of triggering pads spaced apart from each other. Each of the triggering pads has a width within a range from 3 .Math.m to 7 .Math.m, and a distance between any two of the triggering pads adjacent to each other is less than or equal to 2 .Math.m.

A detection method includes forming a complex by binding a target substance and a dielectric particle modified by a single-domain antibody that is bindable to the target substance, separating the complex and an unbound particle in a fluid with dielectrophoresis, the unbound particle being the dielectric particle not forming the complex, and detecting the target substance contained in the separated complex with an imaging element.

A sensor system for sensing dielectric particles of biological material in fluids is disclosed. The sensor system comprises a plurality of electrodes arranged on a substrate, and a dielectrophoretic device arranged on the substrate adjacent to one of the plurality of electrodes and a floating gate field effect transistor with a gate electrode connected to the dielectrophoretic device.

The invention relates to devices for purifying hydraulic and dielectric fluids (oils and fuels) of mechanical impurities. Electric filter for purifying hydraulic and dielectric fluids comprises a housing with an inlet pipe and outlet pipe, high-voltage power supply, composite unit disposed inside the housing and consisting of current-carrying plates and dielectric spacers with apertures for current-carrying and heavy-duty fastening elements, a front plug and rear plug, and current-carrying and heavy-duty fastening elements, wherein the surface of the current-carrying plates is provided with a porous ceramic dielectric coating. The technical result consists in: increasing the efficiency of purifying dielectric fluids; stabilizing the electromagnetic field of the electric filter; increasing the surface area of the electric filter by creating a developed surface of current-carrying filter elements without changing the filter size and mass; improving reliability and ease of use; and reducing the materials consumption.