Magnetohydrodynamic generator

The invention claimed is: 1. A magnetohydrodynamic generator comprising at least: a working fluid flow passage that is defined by a first wall and a second wall; an ionizing device for ionizing the working fluid; a first pair of arms, each connecting together the first and second walls downstream from said ionizing device so as to define, within the flow passage, a channel between the pair of arms and the first and second walls, the channel being arranged to be traversed by a portion of the working fluid after the working fluid has been ionized; a magnet for generating a magnetic field oriented in a direction that is perpendicular to the flow of the working fluid through the channel defined by the pair of arms and the first and second walls; and at least one pair of electrodes, each of the electrodes in each pair of electrodes being arranged on a respective side of the channel defined by the pair of arms and the first and second walls, the electrodes in each pair of electrodes being spaced apart from each other in a direction that is perpendicular to said magnetic field and to the flow direction of the working fluid through the channel defined by the pair of arms and by the first and second walls. 2. The magnetohydrodynamic generator according to claim 1 , wherein each electrode of each pair of electrodes is arranged on a respective arm of the first pair of arms. 3. The magnetohydrodynamic generator according to claim 2 , wherein the magnet includes a core housed inside one of the arms of the first pair of arms. 4. The magnetohydrodynamic generator according to claim 1 , wherein the first and second walls converge towards each other in a flow direction of the working fluid over at least a first segment of the flow passage situated upstream from the first pair of arms. 5. The magnetohydrodynamic generator according to claim 4 , wherein the first and second walls diverge from each other in the flow direction of the working fluid over at least one second segment of the flow passage situated downstream from the pair of arms. 6. The magnetohydrodynamic generator according to claim 1 , wherein the ionizing device is in the form of a plasma torch. 7. The magnetohydrodynamic generator according to claim 1 , including a device for injecting elements of low ionization potential upstream from the ionizing device. 8. The magnetohydrodynamic generator according to claim 1 , including a plurality of pairs of arms, including the first pair of arms, each pair of arms of the plurality of pairs of arms connecting together the first and second walls downstream from the ionizing device, and including a respective magnet and at least one pair of electrodes. 9. The magnetohydrodynamic generator according to claim 1 , wherein said flow passage is annular, said first and second walls being coaxial about a central axis of the flow passage, and said arms being radial. 10. A turbine engine including at least one magnetohydrodynamic generator according to claim 1 , and at a first turbine arranged to be driven by the same working fluid as the magnetohydrodynamic generator. 11. The turbine engine according to claim 10 , including a combustion chamber upstream from the first turbine and from the magnetohydrodynamic generator. 12. The turbine engine according to claim 11 , including at least one compressor upstream from the combustion chamber and wherein the first turbine is coupled to the at least one compressor via a first rotary shaft in order to drive the at least one compressor. 13. The turbine engine according to claim 12 , including a second turbine. 14. The turbine engine according to claim 10 , wherein the magnetohydrodynamic generator is arranged in an outlet nozzle downstream from the first turbine. 15. A magnetohydrodynamic method of generating electricity, wherein: a working fluid is ionized at least in part by an ionizing device in a flow passage defined by first and second walls; and an ionized portion of the working fluid passes through a channel defined in the flow passage by the first and second walls and by a pair of arms, each arm of the pair of arms connecting together the first and second walls downstream from said ionizing device, and the ionized portion of the working fluid passing through the channel is subjected to a magnetic field generated by a magnet, the field extending in the channel in a direction perpendicular to the flow of the working fluid so as to generate an electric current between the electrodes of at least one pair of electrodes, each of the electrodes of each pair of electrodes being arranged on a respective side of the channel defined by the pair of arms and said walls, the electrodes of each pair of electrodes being spaced apart from each other in a direction that is perpendicular both to said magnetic field and to the flow of combustion gas in the channel.