Patent Number: 
Section: claims

1. A device for creating an electromagnetic field, comprising a at least two spiral coils, wherein each spiral coil is made from a segment of conductive material having a fixed length and cross-sectional shape, wherein:a. the segment of conductive material is designed and suited to establish a standing electromagnetic field around said spiral coil when one end of the segment of conductive material is excited by an alternating voltage at an operating frequency which corresponds to the fixed length of the segment of conductive material; and,b. said spiral coil has a wound shape and size which will create inductive-capacitive resonance within said spiral coil, when said spiral coil is excited by the operating frequency which establishes a standing electromagnetic field around said spiral coil;and wherein said spiral coils are positioned proximate to each other in a manner which creates an electromagnetic field between said spiral coils when each of said spiral coils is excited by an operating frequency. 2. The device of claim 1, which has a power factor that is at least 80 percent of an optimal power factor that would be achieved if said alternating voltage were perfectly synchronized with an alternating current response within the segment of conductive material. 3. The device of claim 1, which has a power factor that is at least 90 percent of an optimal power factor that would be achieved if said alternating voltage were perfectly synchronized with an alternating current response within the segment of conductive material. 4. The device of claim 1, which operates as a field-generating electromechanical component within a larger assembly that contains at least two such spiral coils. 5. A reactor device for treating charged particles, comprising at least two spiral coils, wherein each spiral coil is made from a segment of conductive material having a fixed length and cross-sectional shape, wherein:a. the segment of conductive material is designed and suited to establish a standing electromagnetic field around said spiral coil when one end of the segment of conductive material is excited by an alternating voltage at an operating frequency which corresponds to the fixed length of the segment of conductive material; and,b. said spiral coil has a wound shape and size which create inductive-capacitive resonance within said spiral coil, when said coil is excited by said operating frequency which establishes a standing electromagnetic field around said spiral coil;and wherein said spiral coils are positioned proximate to each other in a manner which creates an electromagnetic field between said spiral coils when each of said spiral coils is excited by an operating frequency. 6. The reactor system of claim 1, wherein each spiral coil has a power factor that is at least 80 percent of an optimal power factor that would be achieved if said alternating voltage were perfectly synchronized with an alternating current response within the segment of conductive material. 7. The reactor system of claim 1, wherein each spiral coil has a power factor that is at least 90 percent of an optimal power factor that would be achieved if said alternating voltage were perfectly synchronized with an alternating current response within the segment of conductive material.