Zinc-magnesium anticorrosion pigments, anticorrosion paint, and method for the production of said anticorrosion pigments

The invention claimed is: 1. A platelet-shaped zinc-magnesium pigment, comprising 40.8 to 67.8 mol % of zinc, 32.2 to 59.2 mol % of magnesium and 0 to 7 mol % of at least one metal selected from the group consisting of Mn, Li, Be, Y, Sn, Al, Ti, Fe, Cu and mixtures thereof, based upon the total molar amount of Zn, Mg, Mn, Be, Y, Li, Sn, Al, Ti, Fe and Cu, wherein the molar percentages add up to 100 mol %, and the median thickness h 50 of the pigments is less than 1 μm. 2. The platelet-shaped zinc-magnesium pigment according to claim 1 , wherein the platelet-shaped zinc-magnesium pigment comprises 45.6 to 57.8 mol % of Zn, 42.2 to 54.4 mol % of Mg and 0 to 7 mol % of at least one metal selected from the group consisting of Mn, Li, Be, Y, Sn, Al, Ti, Fe, Cu and mixtures thereof, based upon the total molar amount of Zn, Mg, Mn, Be, Y, Li, Sn, Al, Ti, Fe and Cu, wherein the molar percentages add up to 100 mol % and where Zn, Mg, Mn, Be, Y, Li, Sn, Al, Ti, Fe and Cu constitute at least 93% by weight of the zinc-magnesium pigment based upon the total weight thereof. 3. The platelet-shaped zinc-magnesium pigment according to claim 1 , wherein the platelet-shaped zinc-magnesium pigment comprises less than 0.15 mol % of at least one metal selected from the group consisting of Mn, Li, Be, Y, Sn and mixtures thereof, based upon the total molar amount of Zn, Mg, Mn, Be, Y, Li, Sn, Al, Ti, Fe and Cu. 4. The platelet-shaped zinc-magnesium pigment according to claim 1 , wherein the platelet-shaped zinc-magnesium pigment has a median thickness from a range from 90 nm to less than 700 nm. 5. The platelet-shaped zinc-magnesium pigment according to claim 1 , wherein the platelet-shaped zinc-magnesium pigment has a median diameter D 50 from a range from 3 to 25 μm. 6. The platelet-shaped zinc-magnesium pigment according to claim 1 , wherein the platelet-shaped zinc-magnesium pigment has an aspect ratio within a range from 10 to 200. 7. The platelet-shaped zinc-magnesium pigment according to claim 1 , wherein the platelet-shaped zinc-magnesium pigment has an aspect ratio within a range from 15 to 75. 8. A plurality of platelet-shaped zinc-magnesium pigments according to claim 1 , wherein the platelet-shaped zinc-magnesium pigments have a size distribution having a span ΔD according to formula (II) SpanΔ D =( D 90 − D 10 )/ D 50   (II) of 1.0 to 2.3. 9. The platelet-shaped zinc-magnesium pigment according to claim 1 , wherein the zinc-magnesium pigments comprise 47.3 to 54.2 mol % of Zn, 45.8 to 53.7 mol % of Mg and 0 to 4.6 mol % of at least one metal selected from the group consisting of Mn, Li, Be, Y, Sn, Al, Ti, Fe, Cu and mixtures thereof, based upon the total molar amount of Zn, Mg, Mn, Be, Y, Li, Sn, Al, Ti, Fe and Cu, wherein the molar percentages add up to 100 mol %, the median thickness h 50 of the pigment is less than 700 nm, and where Zn, Mg, Mn, Be, Y, Li, Sn, , Ti, Fe and Cu constitute at least 93% by weight of the zinc-magnesium pigment, based on the total weight thereof. 10. The platelet-shaped zinc-magnesium pigment according to claim 1 , wherein the platelet-shaped zinc-magnesium pigment has been obtained by mechanical forming by means of stirred ball mills as grinding unit. 11. An anticorrosion coating, wherein the anticorrosion coating comprises the platelet-shaped zinc-magnesium pigment of claim 1 . 12. A coating for aircraft or coil coating, comprising the platelet-shaped zinc-magnesium pigment according to claim 1 . 13. An article comprising the zinc-magnesium pigment of claim 1 . 14. The article according to claim 13 , wherein the article is selected from the group consisting of aircraft, ships, boats, motor vehicle bodies, buildings, facades, door and window frames, bridges, power masts and wind turbines. 15. The article according to claim 13 , wherein the article comprises aluminium or an aluminium alloy. 16. A process for producing platelet-shaped anticorrosion pigments according to claim 1 , wherein the process comprises: mechanical forming of non-platelet-shaped zinc-magnesium pigments comprising 40.8 to 67.8 mol % of Zn, 32.2 to 59.2 mol % of Mg and 0 to 7 mol % of at least one metal selected from the group consisting of Mn, Li, Be, Y, Sn, Al, Ti, Fe, Cu and mixtures thereof, based upon the total molar amount of Zn, Mg, Mn, Be, Y, Li, Sn, Al, Ti, Fe and Cu, wherein the molar percentages add up to 100 mol %, and wherein an energy input of at least 2500 kJ per kg of platelet-shaped zinc-magnesium particles is effected at a rate of at least 600 kJ per kg of platelet-shaped zinc-magnesium particles per hour. 17. A process for protecting an article comprising aluminium or an aluminium alloy from corrosion, comprising coating the article with a coating comprising zinc-magnesium pigments according to claim 1 . 18. An article comprising an anticorrosion coating of claim 11 . 19. The article according to claim 13 , wherein the article body consists of aluminium or an aluminium alloy.