Charged particle beam power transmission system

The invention claimed is: 1. An energy extraction system comprising: a decelerator cavity coupled to a transport line for a charged particle beam, the decelerator cavity configured to extract energy from the charged particle beam traveling through the decelerator cavity as RF energy and comprising an active dielectric that, in response to a control signal, actively controls a resonance frequency of the decelerator cavity; an energy conversion device coupled to the decelerator cavity, the energy conversion device configured to convert the RF energy into electrical current and supply the electrical current to an electric power grid, and a control system configured to selectively couple and decouple decoupled the decelerator cavity with the charged particle beam in response to electrical power demand of an electrical load coupled to the energy extraction system by selectively tuning and detuning the decelerator cavity to a resonant frequency of the charged particle beam, the selectively tuning comprising: adjusting the control signal applied to the active dielectric to tune the decelerator cavity to a first resonance frequency that is the resonance frequency of the charged particle beam to couple the decelerator cavity to the charged particle beam; and further adjusting the control signal applied to the active dielectric to de-tune the decelerator cavity to a second resonance frequency that is not the resonance frequency of the charged particle beam to decouple the decelerator cavity from the charged particle beam, wherein the charged particle beam comprises charged particles with individual rest masses greater than the rest mass of an electron. 2. The energy extraction system of claim 1 , wherein the charged particles are charged particle beam comprises protons. 3. The energy extraction system of claim 1 , further comprising a high voltage DC to AC converter coupled to the energy conversion device. 4. The energy extraction system of claim 1 , further comprising: a second decelerator cavity spaced at a distance from the decelerator cavity along the transport line; and a second energy conversion device coupled to the second decelerator cavity, wherein an output of the second energy conversion device is coupled to an output of the energy conversion device; wherein the control system is configured to alternately couple and decouple decoupled the decelerator cavity and the second decelerator cavity with the charged particle beam to produce an AC electrical current output signal. 5. The energy extraction system of claim 4 , wherein the AC electrical current output signal is a 60 Hz AC signal. 6. The energy extraction system of claim 4 , wherein the AC electrical current output signal is a 50 Hz AC signal. 7. The energy extraction system of claim 4 , wherein the control system is configured to: couple the decelerator cavity with the charged particle beam and decouple the second decelerator cavity from the charged particle beam during a first half of a cycle period; and decouple the decelerator cavity from the charged particle beam and couple the second decelerator cavity with the charged particle beam during a second half of the cycle period. 8. The energy extraction system of claim 1 , wherein the energy conversion device comprises a magnetron. 9. The energy extraction system of claim 1 , wherein the energy conversion device comprises an RF solid state diode. 10. The energy extraction system of claim 1 , wherein the decelerator cavity comprises a microwave cavity resonator. 11. An energy extraction system comprising: a decelerator cavity coupled to a transport line for a charged particle beam, the decelerator cavity configured to extract energy from the charged particle beam traveling through the decelerator cavity as RF energy and comprising an active dielectric that, in response to a control signal, actively controls a resonance frequency of the decelerator cavity; means for converting the RF energy into electrical current and supplying the electrical current to an electric power grid, wherein the means is coupled to the decelerator cavity, and a control system configured to selectively couple and decouple decoupled the decelerator cavity with the charged particle beam in response to electrical power demand of an electrical load coupled to the energy extraction system by selectively tuning and detuning the decelerator cavity to a resonant frequency of the charged particle beam, the selectively tuning comprising: adjusting the control signal applied to the active dielectric to tune the decelerator cavity to a first resonance frequency that is the resonance frequency of the charged particle beam to couple the decelerator cavity to the charged particle beam; and further adjusting the control signal applied to the active dielectric to de-tune the decelerator cavity to a second resonance frequency that is not the resonance frequency of the charged particle beam to decouple the decelerator cavity from the charged particle beam, wherein the charged particle beam comprises charged particles with individual rest masses greater than the rest mass of an electron. 12. The energy extraction system of claim 11 , wherein the means for converting the RF energy into electrical current comprises a magnetron. 13. The energy extraction system of claim 11 , wherein the means for converting the RF energy into electrical current and supplying the electrical current to the electric power grid is a first means, and wherein the system further comprises: a second decelerator cavity spaced at a distance from the decelerator cavity along the transport line; and a second means for converting the RF energy into electrical current and supplying the electrical current to the electric power grid, wherein the second means is coupled to the second decelerator cavity, and wherein an output of the second means is coupled to an output of the first means, wherein the control system is configured to alternately couple and decouple decoupled the decelerator cavity and the second decelerator cavity with the charged particle beam to produce an AC electrical current output signal.