Method and magnetic resonance apparatus for correction of a B0 map for chemical shifts

We claim as our invention: 1. A method for correction of a B0 field map measured with a magnetic resonance device in which an examination object is situated, describing deviations from a nominal field strength in a homogeneity area of the magnetic resonance device by deviations from a nominal frequency for protons bonded into water, the deviations being represented as Larmor frequency values for different picture elements resulting from chemical shifts of the Larmor frequencies, wherein the B0 field map was recorded at least in part with spins of fat and water protons in the examination object not in phase, said method comprising: segmenting the B0 field map according to a segmentation criterion that evaluates the differences of the Larmor frequency values of adjacent picture elements of the B0 field map in at least two contiguous clusters, each containing at least two picture elements, that are separated by a jump in the Larmor frequency values; for each cluster, determining, based on a smoothness criterion and a compactness criterion, whether the respective cluster contains a majority of protons bonded into fat; and correcting clusters identified as containing a majority of protons bonded into fat by lowering the Larmor frequency values thereof by a difference between the nominal frequency for protons bonded into water and the corresponding nominal frequency for protons bonded into fat. 2. The method as claimed in claim 1 , comprising using a graph-based segmentation algorithm for the segmentation. 3. The method as claimed in claim 1 , comprising identifying a water reference cluster before the application of the smoothness criterion and the compactness criterion. 4. The method as claimed in claim 3 , comprising determining the water reference cluster as a cluster showing the smallest deviation from the nominal Larmor frequency. 5. The method as claimed in claim 4 comprising determining the water reference cluster as a cluster showing the smallest deviation from the nominal Larmor frequency among a set of the segmented clusters comprising between five and ten of the largest segmented clusters. 6. The method as claimed in claim 4 , comprising forming the median of the Larmor frequency values of the respective cluster for determining the smallest deviation from the nominal Larmor frequency. 7. The method as claimed in claim 3 , comprising using a smoothness of the B0 field map for clusters corrected in testing in relation to the chemical shift as the smoothness criterion for each cluster except for the reference cluster with the smoothness without correction and, when an improved smoothness is established for corrected clusters, accepting the correction and classifying the cluster as a cluster containing a majority of protons bonded into fat. 8. The method as claimed in claim 1 , comprising, as the compactness criterion for each cluster not classified by the smoothness criterion as containing a majority of protons bonded into fat and, if a reference cluster has been defined, as not corresponding to the reference cluster, checking whether an average Larmor frequency value of that cluster is within or outside a permitted interval around an average Larmor frequency value determined for all clusters of the group lying within a region of interest around the cluster to be checked, which contains all clusters classified by the smoothness criterion as containing a majority of protons bonded into fat and, if a reference cluster has been defined, contains the reference cluster, wherein for an average Larmor frequency value lying outside the interval, the checked cluster is classified as containing a majority of protons bonded into fat and corrected. 9. The method as claimed in claim 7 , comprising selecting a slice of the B0 field map containing the cluster to be checked as a region of interest. 10. The method as claimed in claim 1 , comprising determining a fat mask from the clusters classified as containing a majority of protons bonded into fat and using said fat mask in at least one later recording and/or evaluation of magnetic resonance data of the same examination object. 11. The method as claimed in claim 10 comprising using said fat mask as a starting point for a Dixon technique for acquiring magnetic resonance data from said examination object. 12. A method as claimed in claim 10 comprising using said fat mask in an acquisition of magnetic resonance spectroscopic data from said examination object. 13. A magnetic resonance apparatus comprising: a magnetic resonance data acquisition scanner in which an examination subject is situated; a control computer configured to operate said magnetic resonance data acquisition scanner to acquire a B0 field map describing deviations from a nominal field strength in a homogeneity area of the magnetic resonance data acquisition scanner, by deviations from a nominal frequency for protons bonded into water, the deviations being represented as Larmor frequency values for different picture elements resulting from chemical shifts of the Larmor frequencies, with said B0 field map being acquired at least in part with spins of fat and water protons in said examination subject not being in phase; a processing computer provided with said B0 field map, said processing computer being configured to segment the B0 field map according to a segmentation criterion by evaluating differences of the Larmor frequency values of adjacent picture elements of the B0 field map in at least two contiguous clusters, each containing at least two picture elements, that are separated by a jump in the Larmor frequency values; in said processing computer, for each cluster, determining, based on a smoothness criterion and a compactness criterion, whether the respective cluster contains a majority of protons bonded into fat; in said processing computer, correcting clusters identified as containing a majority of protons bonded into fat by lowering the Larmor frequency thereof by a difference between the nominal frequency for protons bonded into water and the corresponding nominal frequency for protons bonded into fat; and generating a corrected B0 field map from all corrected clusters, and making the corrected B0 field map available in electronic form as a data file at an output of said processing computer. 14. A non-transitory, computer-readable data storage medium encoded with programming instructions, said storage medium being loaded into a computer of a magnetic resonance apparatus and said programming instructions causing said computer to: receive a B0 field map, for correction of said B0 field map, acquired by operation of said magnetic resonance apparatus with an examination object situated therein, said B0 field map describing deviations from a nominal field strength of a homogeneity area of the magnetic resonance apparatus by deviations from a nominal frequency for protons bonded into water, the deviations being represented as Larmor frequency values for different picture elements resulting from chemical shifts of the Larmor frequencies, said B0 field map having been acquired at least in part with spins of fat and water protons in the examination object not being in phase; segment the B0 field map according to a segmentation criterion that evaluates the differences of the Larmor frequency values of adjacent picture elements of the B0 field map in at least two contiguous clusters, each containing at least two picture elements, that are separated by a jump in the Larmor frequency values; for each cluster, determine, based on a smoothness criterion and a compactness criterion, whether the respective cluster contains a majority of protons bo