Peripheral hill sector design for cyclotron

The invention claimed is: 1. A magnet pole for use in a cyclotron, comprising at least three hill sectors, each associated with a magnetic field; and a same number of valley sectors alternatively distributed around a central axis, where each valley sector is associated with a magnetic field, where the magnetic fields of the hill sectors are stronger than the magnetic fields of the valley sectors, each hill sector comprising an upper surface defined by: an upper peripheral edge, said upper peripheral edge being bounded by a first and a second upper distal ends, and being defined as the edge of the upper surface located furthest from the central axis, an upper central edge, said upper central edge being bounded by a first and a second upper proximal ends and being defined as the edge of the upper surface located closest from the central axis, a first upper lateral edge connecting the first upper distal end and first upper proximal end, and a second upper lateral edge connecting the second upper distal end and second upper proximal end, wherein the upper peripheral edge of a hill sector comprises an arc of a circle having a center offset with respect to the central axis, and having a radius not more than 85% of a distance from the central axis to a midpoint of the upper peripheral edge, wherein the midpoint is equidistant to the first and second upper distal ends. 2. A magnet pole according to claim 1 , wherein the center lies within the upper surface of the corresponding hill sector. 3. A magnet pole according to claim 2 , wherein the center lies on a bisector of the corresponding upper surface, said bisector being defined as a straight line joining the central axis to the midpoint of the upper peripheral edge. 4. A magnet pole according to claim 1 , wherein the ratio of the radius to the distance from the central axis to the midpoint of the upper peripheral edge is not more than 75%. 5. A magnet pole according to claim 4 , wherein the ratio is not more than 65%. 6. A magnet pole according to claim 1 , wherein the arc extends from the first upper distal end to the second upper distal end of the corresponding upper peripheral edge. 7. A magnet pole according to claim 1 , wherein each valley sector comprises a bottom surface, and each hill sector further comprises: a first lateral surface and a second lateral surface, each extending transversally from the first and second upper lateral edges, to the bottom surfaces of corresponding valley sectors located on either sides of a hill sector, thus defining a first lower lateral edge and a second lower lateral edge as edges intersecting a lateral surface with an adjacent bottom surface, said first and second lower lateral edges each having a lower distal end located furthest from the central axis, and a peripheral surface extending from the upper peripheral edge to a lower peripheral line defined as a segment bounded by the lower distal ends of the first and second lower lateral edges. 8. A magnet pole according to claim 7 , wherein the peripheral surface forms a chamfer adjacent to the upper peripheral edge. 9. A cyclotron for accelerating a particle beam over a given path within a gap, the cyclotron comprising: a first magnet pole and a second magnetic pole, wherein at least one of the first and second magnetic poles comprises: at least three hill sectors, each associated with a magnetic field; and a same number of valley sectors alternatively distributed around a first central axis, where each valley sector is associated with a magnetic field, where the magnetic fields of the hill sectors are stronger than the magnetic fields of the valley sectors, each hill sector comprising an upper surface symmetric with respect to a median plane normal to the first central axis and defined by: an upper peripheral edge bounded by a first and a second upper distal ends and being defined as the edge of the upper surface located furthest from the first central axis, an upper central edge bounded by a first and a second upper proximal ends and being defined as the edge of the upper surface located closest from the first central axis, a first upper lateral edge connecting the first upper distal end and the first upper proximal end, and a second upper lateral edge connecting the second upper distal end and the second upper proximal end, wherein the upper peripheral edge of a hill sector comprises a first arc of a circle having a center offset with respect to the first central axis, and having a radius not more than 85% of a distance from the first central axis to a midpoint of the upper peripheral edge, wherein the midpoint is equidistant to the first and second upper distal ends, wherein the gap is formed between the first magnet pole and the second magnet pole, wherein upper surfaces of the first magnet pole face upper surface of the second magnet pole such that hill gap portions are formed between hill sectors of the first magnet pole and hill sectors of the second magnet pole and such that valley gap portions are formed between valley sectors of the first magnet pole and valley sectors of the second magnet pole. 10. A cyclotron according to claim 9 , further comprising a first point of extraction located in a hill gap portion between two opposite upper surfaces of the first and second magnet poles, wherein the given path of the particle beam is an outward spiral path cycling about the first or second central axis until the first point of extraction whence the particle beam is driven out of the cyclotron with a given energy, and the first and second arcs are parallel to and homothetically reproduce a portion of the given path directly upstream of the first point of extraction. 11. A cyclotron according to claim 10 , further comprising a second point of extraction located downstream from the first point of extraction and within a hill gap portion adjacent to the upper peripheral edges of the two opposite upper surfaces, wherein the particle beam is driven out of the cyclotron with the given energy at the second point of extraction, and wherein the first and second arcs are parallel to and homothetically reproduce a portion of the given path directly upstream of the second point of extraction. 12. A cyclotron according to claim 11 , wherein the particle beam follows a first extraction path downstream of the first point of extraction or follows a second extraction path downstream of the second point of extraction, and wherein the length of the first extraction path is equal to the length of the second extraction path. 13. A cyclotron according to claim 9 , wherein: the upper surface of at least one hill sector of the first magnet pole further comprises: a first recess extending along a longitudinal axis intersecting the first central axis, the first recess being separate from at least 80% of a length of corresponding first and second upper lateral edges, and a first pole insert having a geometry matching the first recess and being positioned in, and reversibly coupled to, the first recess. 14. A cyclotron according to claim 9 , wherein: each valley sector of the first magnet pole comprises a bottom surface; each hill sector of the first magnet pole further comprises a first lateral surface and a second lateral surface, each extending transversally from the first and second upper lateral edges, to the bottom surfaces of corresponding valley sectors located on either sides of a hill sector, thus defining a first lower lateral edge and a second lower lateral edge as edges intersecting a lateral surface with an adjacent bottom surface, the first and second lower lateral edges each having a lowe