Cryostat for superconductive magnet

The invention claimed is: 1. A split closed bore superconducting magnet system having two half magnets, each half magnet comprising: superconducting magnet coils retained in an outer vacuum chamber defining a magnet bore along an axis of rotational symmetry of the split closed bore superconducting magnet system, wherein the two half magnets are spatially separated by a gap along the axis of rotational symmetry; a gradient field coil located between the superconducting magnet coils and the axis of rotational symmetry; and a thermal radiation shield located between the superconducting magnet coils and the outer vacuum chamber, wherein the thermal radiation shield is shaped such that axial spacing between the thermal radiation shields of the half magnets has an internal diameter greater than an outer diameter, and the thermal radiation shield is shaped so as to be absent in a position nearest an imaging region and nearest the gradient field coils of the half magnets. 2. The split closed bore superconducting magnet system according to claim 1 , wherein the thermal radiation shield is shaped so as to be absent in a position nearest the imaging region by a step profile in a cylindrical shape of the thermal radiation shield. 3. The split closed bore superconducting magnet system according to claim 1 , wherein a contour of the thermal radiation shield corresponds with a contour of the outer vacuum chamber. 4. The split closed bore superconducting magnet system according to claim 1 , wherein the thermal radiation shield is chamfered, tapering from a minimum inner diameter to an increased inner diameter. 5. The split closed bore superconducting magnet system according to claim 1 , wherein the thermal radiation shield has a concave dished shape from a minimum inner diameter to an increased inner diameter. 6. The split closed bore superconducting magnet system according to claim 1 , wherein the thermal radiation shield has a convex dished shape from a minimum inner diameter to an increased inner diameter. 7. The split closed bore superconducting magnet system according to claim 1 , wherein each of the two half magnets have recesses provided near an axial and radial extremity of the thermal radiation shield in each of the two half magnets. 8. The split closed bore superconducting magnet system according to claim 7 , wherein the recesses are employed to mount ancillary equipment or to provide improved access for an operator. 9. The split closed bore superconducting magnet system according to claim 1 , further comprising structural components which are encased in the outer vacuum chamber of each of the two half magnets and separate the superconducting magnet coils within each of the two half magnets. 10. The split closed bore superconducting magnet system according to claim 1 , further comprising structural components which support the superconducting magnet coils of each of the two half magnets on the outer vacuum chamber of each half magnet. 11. The A split closed bore superconducting magnet system according to claim 10 , wherein a mechanical support structure bears against each outer vacuum chamber of each half magnet at an axial inner extremity of each of the outer vacuum chambers of each half magnet. 12. The split closed bore superconducting magnet system according to claim 11 , wherein the mechanical support structure is intermittent around a circumference of the split closed bore superconducting magnet system. 13. The split closed bore superconducting magnet system according to claim 10 , wherein a mechanical support structure bears against each outer vacuum chamber of each half magnet at or near an inner diameter of each of the outer vacuum chambers of each half magnet. 14. The split closed bore superconducting magnet system according to claim 10 , wherein a mechanical support structure is attached to a radial outer surface of each of the outer vacuum chambers of each half magnet.