Magnet assembly comprising closed superconducting HTS shims

What is claimed is: 1. A magnet assembly for a magnetic resonance apparatus comprising: a cryostat; a superconducting main field magnet coil system positioned in the cryostat for generating a magnetic field along a z-axis in a working volume centered around z=0 on the z-axis; and a shim device positioned inside the cryostat for adjusting a homogeneity of the magnetic field generated in the working volume by the main field magnet coil system, the shim device comprising a shim conductor path having a high temperature superconductor (HTS) layer in a single closed loop with a winding number of 0 about the z-axis wherein the HTS layer is geometrically developable such that unwrapping the HTS layer onto a plane changes the geodesic distance between any two points on the HTS layer by no more than 10%, and wherein an inner contour or an outer contour of the geometrical development of the HTS layer describes a non-convex curve. 2. The magnet assembly according to claim 1 , wherein the single field gradient corresponds to one of the spherical harmonics z 2 −r 2 /2, z 3 −3/2·zr 2 , r·cos(φ), r·sin(φ), 3rz·cos(φ), 3rz·sin(φ), 3r 2 ·cos(2φ) or 3r 2 ·sin(2φ). 3. The magnet assembly according to claim 1 , wherein the shim conductor path passes through two spaces that are separated from one another by a plane perpendicular to the z-axis, and wherein the magnetic fields generated by conductor portions that extend in the two spaces both having a z-component of the same sign at location z=0 on the z-axis. 4. The magnet assembly according to claim 1 , wherein the shim conductor path passes through an even number of spaces separated from one another by planes perpendicular to the z-axis, and wherein the magnetic fields generated by conductor portions that extend in each case in two adjacent spaces each having a z-component of opposite sign at location z=0 on the z-axis. 5. The magnet assembly according to claim 1 , wherein the shim conductor path passes through four spaces that are separated from one another by a first plane that is perpendicular to the z-axis and by a second plane that contains the z-axis, and wherein the magnetic fields generated by first conductor portions that extend in each case in two spaces adjacent to one another on the first plane each having a z-component of the same sign at location z=0 on the z-axis, and wherein the magnetic fields generated by second conductor portions that extend in each case in two spaces adjacent to one another on the second plane each having a z-component of opposite sign at location z=0 on the z-axis. 6. The magnet assembly according to any claim 1 , wherein the shim conductor path passes through four spaces that are separated from one another by a first plane that is perpendicular to the z-axis and by a second plane that contains the z-axis, and wherein the magnetic fields generated by conductor portions that extend in each case in two adjacent spaces each having a z-component of opposite sign at location z=0 on the z-axis. 7. The magnet assembly according to claim 1 , wherein the shim conductor path passes through eight spaces that are separated from one another by a first plane that is perpendicular to the z-axis and by a second plane and a third plane that contain the z-axis and are perpendicular to one another, and wherein the magnetic fields generated by first conductor portions that extend in each case in two spaces adjacent to one another on the first plane each having a z-component of the same sign at location z=0 on the z-axis, and wherein the magnetic fields generated by second conductor portions that extend in each case in two spaces adjacent to one another on the second plane or third plane each having a z-component of opposite sign at location z=0 on the z-axis. 8. The magnet assembly according to claim 1 , wherein, when projected on a cylinder about the z-axis, the shim conductor path comprises more than two conductor portions that extend in an azimuthal direction and are electrically interconnected by connecting portions extending in other directions. 9. The magnet assembly according to claim 1 , wherein the shim conductor path is produced from an HTS strip conductor or from an HTS-coated film, the HTS material comprising a rare earth metal-Barium-Copper oxide (ReBCO) or a Bismuth-Strontium-Calcium-Copper oxide (BSCCO). 10. The magnet assembly of claim 9 , wherein the ReBCO comprises Yttrium-Barium-Copper oxide (YBCO) or Gadolinium-Barium-Copper oxide (GdBCO). 11. The magnet assembly according to claim 1 , wherein the shim device comprises a plurality of shim conductor paths that are inductively decoupled from one another. 12. The magnet assembly according to claim 11 , wherein the mutual inductance L 12 between any two of the shim conductor paths is given by |L 12 |/√{square root over (L 1 L 2 )}≤0.2, L 1 and L 2 being the self-inductance of the two shim conductor paths. 13. The magnet assembly according to claim 1 , wherein, when projected on a cylinder about the z-axis, the shim conductor path overlaps or intersects with itself. 14. The magnet assembly of claim 13 , wherein the shim conductor path is coiled cylindrically, in more than one layer, around the working volume, or such that the geometrically developable HTS layer exhibits at least one change in direction of revolution about the z-axis. 15. The magnet assembly according to claim 1 , wherein the shim device comprises a plurality of shim conductor paths that are arranged so as to be radially above one another relative to the z-axis and extend axially and azimuthally in an identical manner. 16. The magnet assembly according to claim 1 , wherein the shim conductor path includes a superconducting switch. 17. The magnet assembly according to claim 1 , wherein the superconducting main field magnet coil system comprises coils made of an HTS conductor, and wherein the superconducting main field magnet coil system and the shim device are cooled by a cryocooler to a temperature of between 10 K and 80 K. 18. The magnet assembly according to claim 1 , wherein the shim conductor path extends, with respect to the z-axis, radially inside the superconducting main field magnet coil system at least in part. 19. An active shim device comprising: a shim conductor path through a high temperature superconductor (HTS) layer in a single closed loop that is geometrically developable such that unwrapping the HTS layer onto a plane changes the geodesic distance between any two points on the HTS layer by no more than 10%, wherein an inner contour or an outer contour of the geometrical development of the HTS layer describes a non-convex curve, and wherein the shim conductor path generates a shimming magnetic field with an axial component B z (r, z, φ) with respect to a cylindrical coordinate system about a z-axis, the shimming magnetic field comprising primarily a single field gradient represented in a basis of spherical harmonics about z=0 on a z-axis of a magnetic field of a superconducting main field magnet coil system, in addition to a non-vanishing field gradient of zero degree. 20. The magnet assembly according to claim 1 , wherein, the shim conductor path generates a shimming magnetic field with an axial component B z (r, z, φ) with respect to a cylindrical coordinate system about the z-axis, the shimming magnetic field comprising primarily a single field gradient represented in a basis of spherical harmonics about z=0, in addition to a non-vanishing field gradient of zero degree.