A device for separating a sample of cells suspended in a bio-compatible ferrofluid is described. The device includes a microfluidic channel having a sample inlet, at least one output, and a length between the sample inlet and the at least one output, wherein a sample can be added to the sample inlet and flow along the length to the at least one outlet. The device includes a plurality of electrodes, wherein the microfluidic channel length transverses the plurality of electrodes, and further includes a power source for applying a current to the plurality of electrodes to create a magnetic field pattern along the length of the microfluidic channel. The present invention also includes a method for separating at least one cell type. The method includes the steps of suspending cells in a bio-compatible ferrofluid to form a sample, passing the sample through a microfluidic channel that transverses a plurality of electrodes, applying a current to the plurality of electrodes to create a magnetic field pattern along the length of the microfluidic channel, and sorting the ceils into at least one output channel based on a variation of at least one of cell size, shape and elasticity.

A method for magnetic cellular manipulation may include contacting a composition with a biological sample to form a mixture. The composition may include a plurality of particles. Each particle in the plurality of particles may include a magnetic substrate. The magnetic substrate may be characterized by a magnetic susceptibility greater than zero. The composition may also include a chargeable silicon-containing compound. The chargeable silicon-containing compound may coat at least a portion of the magnetic substrate. The biological sample may include cells and/or cellular structures. The method may also include applying a magnetic field to the mixture to manipulate the composition.

A device and method is provided for separating associated ions within a gaseous fluid stream into a first population of positively-charged hydrated hydrogen ions and a second population of gaseous hydrated anions. The device employs a housing and spinning wheel within a vacuum chamber to expose a flow of associated ions to a combination of microwaves and magnetic energy within the vacuum to cause bifurcation of the associated ions into a first population of positively-charged hydrated hydrogen ions and a second population of gaseous hydrated anions which may be collected in reservoirs. The collected two populations can be further channeled through a transformer to electrically induce a force for locomotion or communication.

A device and method is provided for separating associated ions within a gaseous fluid stream into a first population of positively-charged hydrated hydrogen ions and a second population of gaseous hydrated anions. The device employs a housing and spinning wheel within a vacuum chamber to expose a flow of associated ions to a combination of microwaves and magnetic energy within the vacuum to cause bifurcation of the associated ions into a first population of positively-charged hydrated hydrogen ions and a second population of gaseous hydrated anions which may be collected in reservoirs. The collected two populations can be further channeled through a transformer to electrically induce a force for locomotion or communication.

A device and method of reclaiming refractory material from a lining of a refractory includes assembling a first refractory component of the lining with a first refractory product, and assembling a second refractory component of the working lining with a second refractory product different from the first refractory product, the second refractory product including magnetic material dispersed therein. Upon the lining reaching a service life, the lining is demolished to produce a mixture of the first refractory component pieces and the second refractory component pieces. Magnetic separation is performed on the mixture to separate the second refractory component pieces from the first refractory component pieces.

A device and method of reclaiming refractory material from a lining of a refractory includes assembling a first refractory component of the lining with a first refractory product, and assembling a second refractory component of the working lining with a second refractory product different from the first refractory product, the second refractory product including magnetic material dispersed therein. Upon the lining reaching a service life, the lining is demolished to produce a mixture of the first refractory component pieces and the second refractory component pieces. Magnetic separation is performed on the mixture to separate the second refractory component pieces from the first refractory component pieces.

Devices are provided comprising one or more insulated hollow vertical pipes inserted into a bed of soil, each pipe having a descending and an ascending conductive element forming a loop within the interior of the pipe. A plurality of such vertical pipes can be attached to a straight pipe, forming a two dimensional array of vertical pipes, in which the loops are connected in series. Further, a series of such one-dimensional straight pipes can be attached together to provide a two-dimensional array. When vertical pipes are inserted into the bed of soil and an electrical current applied to the array, one or more magnetic fields is produced within the bed and parallel to the surface of the bed. The magnetic fields so produced impede downward flow of ionic fertilizers into the ground water, and retaining the fertilizer near growing plants when the bed is irrigated.

Devices are provided comprising one or more insulated hollow vertical pipes inserted into a bed of soil, each pipe having a descending and an ascending conductive element forming a loop within the interior of the pipe. A plurality of such vertical pipes can be attached to a straight pipe, forming a two dimensional array of vertical pipes, in which the loops are connected in series. Further, a series of such one-dimensional straight pipes can be attached together to provide a two-dimensional array. When vertical pipes are inserted into the bed of soil and an electrical current applied to the array, one or more magnetic fields is produced within the bed and parallel to the surface of the bed. The magnetic fields so produced impede downward flow of ionic fertilizers into the ground water, and retaining the fertilizer near growing plants when the bed is irrigated.

Devices are provided comprising one or more insulated hollow vertical pipes inserted into a bed of soil, each pipe having a descending and an ascending conductive element forming a loop within the interior of the pipe. A plurality of such vertical pipes can be attached to a straight pipe, forming a two dimensional array of vertical pipes, in which the loops are connected in series. Further, a series of such one-dimensional straight pipes can be attached together to provide a two-dimensional array. When vertical pipes are inserted into the bed of soil and an electrical current applied to the array, one or more magnetic fields is produced within the bed and parallel to the surface of the bed. The magnetic fields so produced impede downward flow of ionic fertilizers into the ground water, and retaining the fertilizer near growing plants when the bed is irrigated.

Devices are provided comprising one or more insulated hollow vertical pipes inserted into a bed of soil, each pipe having a descending and an ascending conductive element forming a loop within the interior of the pipe. A plurality of such vertical pipes can be attached to a straight pipe, forming a two dimensional array of vertical pipes, in which the loops are connected in series. Further, a series of such one-dimensional straight pipes can be attached together to provide a two-dimensional array. When vertical pipes are inserted into the bed of soil and an electrical current applied to the array, one or more magnetic fields is produced within the bed and parallel to the surface of the bed. The magnetic fields so produced impede downward flow of ionic fertilizers into the ground water, and retaining the fertilizer near growing plants when the bed is irrigated.