Magnetron powered linear accelerator for interleaved multi-energy operation

What is claimed is: 1. A method of generating a high dose rate of electrons of different energies using a traveling wave linear accelerator, the method comprising: coupling a first electromagnetic wave generated by a magnetron into the traveling wave linear accelerator; applying a first originating electron beam current to an electron gun to eject a first beam of electrons from the electron gun into the traveling wave linear accelerator, wherein the first beam of electrons has a first pulse length and is accelerated by the first electromagnetic wave to a first range of energies and output at a first captured electron beam current; coupling a second electromagnetic wave generated by the magnetron into the traveling wave linear accelerator; and applying a second originating electron beam current to the electron gun to eject a second beam of electrons from the electron gun into the traveling wave linear accelerator, wherein the second beam of electrons has a second pulse length that is different from the first pulse length and is accelerated by the second electromagnetic wave to a second range of energies and output at a second captured electron beam current, wherein a magnitude of the second captured electron beam current is different from a magnitude of the first captured electron beam current, wherein an energy output of the traveling wave linear accelerator is controlled by alternating between the first pulse length and the second pulse length and by further varying at least one of a) an originating electron beam current between the first originating electron beam current and the second originating electron beam current or b) a captured electron beam current between the first captured electron beam current and the second captured electron beam current, wherein a central value of the second range of energies is different from a central value of the first range of energies, and wherein the second range of energies and the first range of energies are interleaved. 2. The method of claim 1 , wherein the magnitude of the second captured electron beam current differs from the magnitude of the first captured electron beam current by about 160 mA, and wherein the central value of the second range of energies differs from the central value of the first range of energies by about 3 MeV. 3. The method of claim 1 , wherein the magnitude of the second captured electron beam current differs from the magnitude of the first captured electron beam current by about 53 mA for each approximately 1 MeV difference between the central value of the second range of energies and the central value of the first range of energies. 4. The method of claim 1 , wherein the magnitude of the second captured electron beam current is less than the magnitude of the first captured electron beam current, and wherein the central value of the second range of energies is greater than the central value of the first range of energies. 5. The method of claim 1 , wherein the magnitude of the second captured electron beam current is greater than the magnitude of the first captured electron beam current, and wherein the central value of the second range of energies is less than the central value of the first range of energies. 6. The method of claim 1 , wherein the second pulse length of the second beam of electrons is shorter than the first pulse length of the first beam of electrons. 7. The method of claim 1 , wherein the second pulse length of the second beam of electrons is longer than the first pulse length of the first beam of electrons. 8. The method of claim 1 , wherein the central value of the first range of energies and the central value of the second range of energies is a median value or an average value. 9. The method of claim 1 , wherein a frequency of the first electromagnetic wave is approximately equal to a frequency of the second electromagnetic wave, and wherein an amplitude of the first electromagnetic wave is approximately equal to an amplitude of the second electromagnetic wave. 10. The method of claim 1 , wherein a frequency of the second electromagnetic wave is different from a frequency of the first electromagnetic wave by less than about 0.002%. 11. The method of claim 1 , further comprising monitoring a first phase shift of the first electromagnetic wave using a frequency controller interfaced with an input and an output of the traveling wave linear accelerator, wherein the frequency controller compares a phase of the first electromagnetic wave at the input of the traveling wave linear accelerator to a phase of the first electromagnetic wave near the output of the traveling wave linear accelerator to determine a phase shift, wherein the frequency controller transmits a tuning signal to a tuner based on the phase shift. 12. A method of generating beams of x-rays at two different ranges of x-ray energies from a target positioned near a first end of a traveling wave linear accelerator, wherein an electron gun is positioned at a second end of the traveling wave linear accelerator opposite to the first end, the method comprising: coupling a first electromagnetic wave generated by the magnetron into the traveling wave linear accelerator; ejecting a first beam of electrons from an electron gun into the traveling wave linear accelerator, wherein the first beam of electrons has a first pulse length and is accelerated by the first electromagnetic wave to a first range of energies and output at a first captured electron beam current; contacting the target with the first beam of electrons at the first energy, thereby generating a first beam of x-rays having energies in a first range of x-ray energies from the target; coupling a second electromagnetic wave generated by the magnetron into the traveling wave linear accelerator; ejecting a second beam of electrons from the electron gun, wherein the second beam of electrons has a second pulse length that is different from the first pulse length and is accelerated by the second electromagnetic wave to a second range of energies and output at a second captured electron beam current; wherein a magnitude of the second captured electron beam current is different from a magnitude of the first captured electron beam current, wherein an energy output of the traveling wave linear accelerator is controlled by alternating between the first pulse length and the second pulse length and by further varying a captured electron beam current between the first captured electron beam current and the second captured electron beam current, and wherein a central value of the second energy is different from a central value of the first energy; and contacting the target with the second beam of electrons at the second energy, to generate a second beam of x-rays having energies in a second range of x-ray energies from the target. 13. The method of claim 12 , wherein the second range of x-ray energies and the first range of x-ray energies are interleaved. 14. The method of claim 12 , wherein the magnitude of the second captured electron beam current differs from the magnitude of the first captured electron beam current by about 53 mA for each approximately 1 MeV difference between the central value of the second range of energies and the central value of the first range of energies. 15. The method of claim 12 , wherein the magnitude of the second captured electron beam current is less than the magnitude of the first captured electron beam current, and wherein the central value of the second range of x-ray energies is greater than the central value of the first range of x-ray energies. 16. The method of clai