Method for processing a carrier, a carrier, an electronic device and a lithographic mask

What is claimed is: 1. A carrier, the carrier comprising, a doping profile comprising implanted ions, wherein the doping profile is generated by changing the three-dimensional structure of a mask layer arranged over the carrier so that at least two mask layer regions are formed having different mask layer thicknesses, wherein changing the three-dimensional structure of the mask layer comprises forming at least a first mask layer region comprising a gradual decrease of the thickness of the mask layer along a predefined direction parallel to a surface of the carrier and at least a second mask layer region comprising a gradual increase of the thickness of the mask layer along the same direction; and applying an ion implantation process to the at least two mask layer regions to form at least two implanted regions in the carrier having different implantation depth profiles. 2. A carrier, the carrier comprising, implanted material in a first region of the carrier, wherein the implantation depth of the implanted material in the first region of the carrier is continuously substantially linearly decreasing along a predefined direction parallel to the surface of the carrier; and implanted material in a second region of the carrier, wherein the implantation depth of the implanted material in the second region of the carrier is continuously substantially linearly increasing along the predefined direction. 3. The carrier according to claim 2 , wherein the spatial distribution of the implanted material has a Gaussian dependence at least for the material distribution along a direction parallel to the implantation direction. 4. The carrier according to claim 2 , wherein the spatial distribution of the implanted material includes regions having the same implanted material concentration, wherein the regions having the same implanted material concentration form planar layers, which are not perpendicular to the implantation direction and not parallel to the surface of the carrier. 5. An electronic device, comprising: a carrier comprising: implanted material in a first region of the carrier, wherein the implantation depth of the implanted material in the first region of the carrier is continuously substantially linearly decreasing along a predefined direction parallel to the surface of the carrier; and implanted material in a second region of the carrier, wherein the implantation depth of the implanted material in the second region of the carrier is continuously substantially linearly increasing along the predefined direction. 6. The electronic device of claim 5 , being configured as at least one of transistor, a diode, an optical sensor, a strain sensor, and a hall sensor. 7. The electronic device of claim 5 , wherein the spatial distribution of the implanted material includes regions having the same implanted material concentration, wherein the regions having the same implanted material concentration form planar layers which are not perpendicular to the implantation direction and not parallel to the surface of the carrier. 8. The electronic device of claim 5 , wherein the implanted material in the first region of the carrier and the implanted material in the second region of the carrier form a V-shaped doped region. 9. The electronic device of claim 8 , further comprising: implanted contact regions for contacting the V-shaped doped region. 10. The electronic device of claim 9 , wherein the contact regions form at least one V-shaped doped contact region. 11. The electronic device of claim 10 , wherein the at least one V-shaped doped contact region is aligned perpendicular to the V-shaped doped region.