The system extracts water from lunar regolith and includes a regolith intake having a digging bucket that collects lunar regolith soil and a gravel separator that separates and discharges gravel and passes a mixture of ice-regolith powder having ice grains that are about 10-100 microns along the conveyor. A pneumatic separator receives the ice-regolith powder and pneumatically splits the ice-regolith powder into streams of different sized lithic fragments and ice particles per the ratio of inertial force and aerodynamic drag force of the lithic fragments and ice particles. Each split stream may include a magnetic separator that separates further the magnetic and paramagnetic lithic fragments from ice particles to discharge up to 80 percent of lithic fragments to slag.

The system extracts water from lunar regolith and includes a regolith intake having a digging bucket that collects lunar regolith soil and a gravel separator that separates and discharges gravel and passes a mixture of ice-regolith powder having ice grains that are about 10-100 microns along the conveyor. A pneumatic separator receives the ice-regolith powder and pneumatically splits the ice-regolith powder into streams of different sized lithic fragments and ice particles per the ratio of inertial force and aerodynamic drag force of the lithic fragments and ice particles. Each split stream may include a magnetic separator that separates further the magnetic and paramagnetic lithic fragments from ice particles to discharge up to 80 percent of lithic fragments to slag.

A method of generating an electrostatic attraction force includes an application of an insulating surface, wherein the insulating surface separates electrode arrays and the electrode arrays positioned in at least two different axes and providing an adhesion with an help of the electrostatic attraction force, wherein a matrix array is formed for an electrostatic attraction force region to provide gravity to at least one of objects, at a desired point and a number of electrodes is generated by feeding with a DC voltage and/or an AC voltage at desired points and at a desired force, wherein at least two objects adhere with the electrostatic attraction force.

A method of generating an electrostatic attraction force includes an application of an insulating surface, wherein the insulating surface separates electrode arrays and the electrode arrays positioned in at least two different axes and providing an adhesion with an help of the electrostatic attraction force, wherein a matrix array is formed for an electrostatic attraction force region to provide gravity to at least one of objects, at a desired point and a number of electrodes is generated by feeding with a DC voltage and/or an AC voltage at desired points and at a desired force, wherein at least two objects adhere with the electrostatic attraction force.

A photoelectrical device for detection of bacterial cell density includes a substrate, a driving electrode layer, an AC power source and a photoelectric conversion layer. The driving electrode layer is disposed on the substrate and includes a central electrode and a peripheral electrode pattern surrounding the central electrode. A fluid sample is disposed on the driving electrode layer. The AC power source is electrically connected to the driving electrode layer, and used to produce a non-uniform alternating electric field in the fluid sample on the driving electrode layer for driving the target bioparticles to gather up on the central electrode to form a particle cluster. The photoelectric conversion layer is used for receiving a light detecting beam after passing through the particle cluster and outputting an electric current based on the optical density of light detecting beam. The electric current changes as a concentration of the target bioparticles changes.

A method of generating an electrostatic attraction force includes an application of an insulating surface, wherein the insulating surface separates electrode arrays and the electrode arrays positioned in at least two different axes and providing an adhesion with an help of the electrostatic attraction force, wherein a matrix array is formed for an electrostatic attraction force region to provide gravity to at least one of objects, at a desired point and a number of electrodes is generated by feeding with a DC voltage and/or an AC voltage at desired points and at a desired force, wherein at least two objects adhere with the electrostatic attraction force.

A method of generating an electrostatic attraction force includes an application of an insulating surface, wherein the insulating surface separates electrode arrays and the electrode arrays positioned in at least two different axes and providing an adhesion with an help of the electrostatic attraction force, wherein a matrix array is formed for an electrostatic attraction force region to provide gravity to at least one of objects, at a desired point and a number of electrodes is generated by feeding with a DC voltage and/or an AC voltage at desired points and at a desired force, wherein at least two objects adhere with the electrostatic attraction force.

An electrostatic separator separates conductive particles from raw materials includes: a container with a raw material layer; a gas dispersion plate at the bottom of the raw material layer; at least one vibrating body in the raw material layer flush with the gas dispersion plate or above it; a fluidization gas supplier introduced from the container bottom into the raw material layer flows upward through the gas dispersion plate; an upper electrode above the raw material layer; a lower electrode in the raw material layer, the lower electrode being flush with the gas dispersion plate or above it; a power supply applies a voltage between the upper and lower electrode wherein one becomes a negative electrode, the other becomes a positive electrode, and an electric field is generated between them; and a capturer captures conductive particles that have flown out of the raw material layer surface toward the upper electrode.

Methods and apparatus for separating, concentrating and/or detecting molecules based on differences in binding affinity to a probe are provided. The molecules may be differentially modified. The molecules may be differentially methylated nucleic acids. The methods can be used in fields such as epigenetics or oncology to selectively concentrate or detect the presence of specific biomolecules or differentially modified biomolecules, to provide diagnostics for disorders such as fetal genetic disorders, to detect biomarkers in cancer, organ failure, disease states, infection or the like.

A group of micro-objects in a holding pen in a micro-fluidic device can be selected and moved to a staging area, from which the micro-objects can be exported from the micro-fluidic device. The micro-fluidic device can have a plurality of holding pens, and each holding pen can isolate micro-objects located in the holding pen from micro-objects located in the other holding pens or elsewhere in the micro-fluidic device. The selected group of micro-objects can comprise one or more biological cells, such as a clonal population of cells. Embodiments of the invention can thus select a particular group of clonal cells in a micro-fluidic device, move the clonal cells to a staging area, and export the clonal cells from the micro-fluidic device while maintaining the clonal nature of the exported group.