MPD thruster that accelerates electrodeless plasma and electrodeless plasma accelerating method using MPD thruster

The invention claimed is: 1. An MPD thruster comprising: an electrodeless plasma generating device configured to generate electrodeless plasma from propellant; an accelerating device configured to accelerate the electrodeless plasma; and a supply passage configured to supply the electrodeless plasma which has been generated to the accelerating device, wherein the accelerating device comprises: a magnetic coil; a cathode; an anode; a nozzle configured to emit the electrodeless plasma which has been accelerated; and a voltage applying unit configured to apply a voltage between the cathode and the anode, wherein the supply passage supplies the electrodeless plasma to a space between the cathode and the anode, wherein the magnetic coil generates an axial direction magnetic field component along a direction of a center axis of the MPD thruster and a radial direction magnetic field component orthogonal to the center axis of the MPD thruster in the space, the space being positioned downstream of the supply passage, wherein the voltage applying unit generates a current in the space, wherein the electrodeless plasma supplied to the space is accelerated with Lorentz force induced by the axial direction magnetic field component, the radial direction magnetic field component, and the current, wherein the anode constitutes at least a part of an inner surface of the nozzle, wherein an entirety of the anode is positioned downstream of the magnetic coil, and wherein the supply passage includes a plurality of supply pipes arranged around the cathode. 2. The MPD thruster according to claim 1 , wherein a distance between the supply passage and the center axis of the MPD thruster is larger than a distance between the cathode and the center axis of the MPD thruster and is smaller than a distance between the anode and the center axis of the MPD thruster. 3. The MPD thruster according to claim 1 , wherein the cathode is arranged along the center axis of the MPD thruster. 4. The MPD thruster according to claim 1 , wherein the electrodeless plasma generating device comprises an antenna arranged around the supply passage, and wherein the electrodeless plasma generating device converts the propellant to the electrodeless plasma through interaction of an electric field induced by the antenna and the magnetic field generated by the magnetic coil. 5. The MPD thruster according to claim 4 , wherein the supply pipes are arranged at equal intervals around the cathode, wherein the antenna is one of a plurality of antennas, and wherein a corresponding one of the plurality of antennas is arranged around each of the plurality of supply pipes. 6. The MPD thruster according to claim 5 , wherein the electrodeless plasma generating device further comprises: one power supply; and an impedance matching device, wherein the power supply is configured to drive the plurality of antennas through the impedance matching device. 7. The MPD thruster according to claim 4 , wherein the antenna is a helical antenna and the electrodeless plasma is helicon plasma. 8. The MPD thruster according to claim 1 , wherein the cathode is a hollow cathode. 9. An electrodeless plasma accelerating method using an MPD thruster, comprising: by using a supply passage, supplying electrodeless plasma to a space between a cathode and an anode to reduce a resistivity in the space, the space being positioned downstream of the supply passage; by using a magnetic coil, generating an axial direction magnetic field component along a direction of a center axis of the MPD thruster and a radial direction magnetic field component orthogonal to the center axis of the MPD thruster in the space; generating a current in the space; accelerating electrodeless plasma with Lorentz force induced by the axial direction magnetic field component, the radial direction magnetic field component and the current; and emitting the electrodeless plasma which has been accelerated from a nozzle, wherein the anode constitutes at least a part of an inner surface of the nozzle, wherein an entirety of the anode is positioned downstream of the magnetic coil, and wherein the supply passage includes a plurality of supply pipes arranged around the cathode. 10. The MPD thruster according to claim 1 , wherein the supply pipes are positioned at equal intervals around the cathode. 11. The MPD thruster according to claim 1 , wherein the supply pipes are positioned so as to be spaced from the cathode. 12. The MPD thruster according to claim 5 , wherein the magnetic coil is positioned to at least partially overlap the plurality of antennas in the direction of the center axis of the MPD thruster. 13. The method according to claim 9 , wherein the supply pipes are positioned at equal intervals around the cathode. 14. The method according to claim 9 , wherein the supply pipes are positioned so as to be spaced from the cathode. 15. The method according to claim 9 , wherein the magnetic coil is positioned to at least partially overlap the plurality of antennas in the direction of the center axis of the MPD thruster.