Method for charging a superconductor bulk magnet by field-cooling, with at least one non-homogeneous magnetic field component of the applied charger magnetic field

What is claimed is: 1 . A method for charging a superconductor bulk magnet by field-cooling using a magnet charger system, wherein the magnet charger system comprises a background charger magnet and a field adjustment unit, wherein the superconductor bulk magnet comprises a bulk magnet bore, wherein the bulk magnet bore contains a sample volume, wherein the background charger magnet comprises a charger bore, wherein the superconductor bulk magnet is arranged within the charger bore, wherein the background charger magnet and the field adjustment unit are arranged radially outside the bulk magnet bore, and wherein the superconductor bulk magnet has a critical temperature T c ; said method comprising: step a) charging the magnet charger system to thereafter generate a first magnetic field in the sample volume, wherein the superconductor bulk magnet has a temperature T, with T>T c ; step b) cooling the superconductor bulk magnet to a temperature T<T c ; step c) discharging the magnet charger system, which inductively charges the superconductor bulk magnet, such that the superconductor bulk magnet traps a second magnetic field in the sample volume; before said step a), determining a correlation between a magnetic field applied by the magnet charger system from outside the superconductor bulk magnet and a resulting magnetic field trapped by the superconductor bulk magnet at least approximately in the sample volume, in said step a), setting the field adjustment unit such that the first magnetic field generated by the magnet charger system in the sample volume comprises a homogeneous magnetic field component and at least one non-homogeneous magnetic field component, wherein the at least one non-homogeneous field component is chosen, using the correlation, such that the second magnetic field of said step c) has a higher homogeneity than the first magnetic field of said step a) in the sample volume, wherein the correlation is chosen with a linear function for each applied non-homogeneous magnetic field component comprised in the first magnetic field and to be adjusted by the field adjustment unit, wherein each linear function is defined by a slope and an offset, and correlates a component strength value of the magnetic field applied with a corresponding component strength value of the magnetic field trapped for the non-homogeneous magnetic field component, and wherein said determining of the correlation includes at least determining the offset for each linear function by calculation and/or by measurement. 2 . Method according to claim 1 , wherein, for at least a majority of the applied non-homogeneous magnetic field components comprised in the first magnetic field and adjusted by the field adjustment unit, a corresponding applied component strength value of the first magnetic field is larger in absolute value than is a corresponding trapped component strength value in the second magnetic field. 3 . Method according to claim 2 , wherein, for each of the applied non-homogeneous magnetic field components comprised in the first magnetic field and adjusted by the field adjustment unit, the corresponding applied component strength value of the first magnetic field is larger in absolute value than is the corresponding trapped component strength value in the second magnetic field. 4 . Method according to claim 1 , wherein the at least one non-homogeneous magnetic field component of the first magnetic field is one or a plurality of gradient components of the first magnetic field. 5 . Method according to claim 4 , wherein the field adjustment unit comprises a plurality of field adjustment coils, allowing a direct adjustment of one or a plurality of individual gradient components. 6 . Method according to claim 4 , wherein the gradient components are associated with first or higher order spherical harmonics. 7 . Method according to claim 5 , wherein the field adjustment unit is chosen with a field adjustment coil or set of field adjustment coils for each gradient component. 8 . Method according to claim 1 , wherein, for at least approximately determining the correlation, before a cycle of said steps a), b) and c), at least one preparatory cycle of steps is applied, with each preparatory cycle of said steps comprising: step a′) charging the magnet charger system, such that said charging generates a first provisional magnetic field in the sample volume, wherein a magnetic field profile of the first provisional magnetic field is measured or calculated, wherein the superconductor bulk magnet has a temperature T, with T>T c ; step b′) cooling the superconductor bulk magnet to a temperature T<T c ; step c′) discharging the magnet charger system, which inductively charges the superconductor bulk magnet, such that the superconductor bulk magnet traps a second provisional magnetic field in the sample volume, wherein a magnetic field profile of the second provisional magnetic field is measured. 9 . Method according to claim 8 , wherein: during said step a′), a respective applied component strength value for each of the at least one non-homogeneous magnetic field component to be adjusted by the field adjustment unit is determined from the measured or calculated magnetic field profile of the first provisional magnetic field, and during said step c′), a respective trapped component strength value for each of the at least one non-homogeneous magnetic field component to be adjusted by the field adjustment unit is determined from the measured magnetic field profile of the second provisional magnetic field. 10 . Method according to claim 9 , wherein: during a next cycle of said steps a), b), c) or during a next preparatory cycle of said steps a′), b′), c′), in a respective next step a) or next step a′), the field adjustment unit is set such that a respective non-homogeneous magnetic field component of the first magnetic field to be adjusted by the field adjustment unit is chosen with a next applied component strength value being the applied component strength value of said previous step a′) minus the trapped component strength value of the previous preparatory cycle of steps. 11 . Method according to claim 8 , wherein, in said step c), a magnetic field profile of the second magnetic field is measured, wherein, in each said step c′) and said step c), the homogeneity of the measured second provisional magnetic field or the second magnetic field in the sample volume is compared to a predefined homogeneity threshold, and when the homogeneity of the measured second provisional magnetic field is worse than the homogeneity threshold in said step c′), then another preparatory cycle of said steps a′), b′), c′) or another cycle of said steps a), b) and c) is performed, and when the homogeneity of the measured second magnetic field is equal to or better than the homogeneity threshold in said step c), then the second magnetic field in the sample volume is retained, and the method ends. 12 . Method according to claim 8 , wherein the magnetic field profile of the first provisional magnetic field is measured or calculated from electric currents applied to the magnet charger system. 13 . Method according to claim 1 , wherein, for at least approximately determining the correlation, before a cycle of said steps a), b) and c), a magnetic field trapping behavior of the magnet charger system and the superconductor bulk magnet is calculated in advance, taking into account at least a geometry of the magnet charger system or a magnetic field of the magnet charger system, and a geometry of the superconductor bulk magnet. 14 . Method according to claim 13 ,