Catalyst for reduction of nitrogen oxides

The invention claimed is: 1. Nitrogen oxide storage catalyst composed of at least two catalytically active washcoat layers on a support body, wherein a lower washcoat layer A contains cerium oxide in a quantity of 110 to 180 kg/m 3 (110 to 180 g/L) in relation to the volume of the support body, an alkaline earth metal compound and/or an alkali metal compound, as well as platinum and palladium; an upper washcoat layer B disposed atop the washcoat layer A contains cerium oxide, as well as platinum and palladium, and no alkali metal or alkaline earth metal compounds; the ratio of the cerium oxide in washcoat layer A to the cerium oxide in washcoat layer B is greater than 1:1 up to 5:1, wherein the total quantity of cerium oxide in washcoat layer A and washcoat layer B, calculated in kg/m 3 (g/L) and in relation to the volume of the support body, is 132 to 240 kg/m 3 (132 to 240 g/L); the ratio Pt:Pd in washcoat layer A and washcoat layer B is equal, and the ratio Pt:Pd amounts to 2:1 to 20:1; the total quantity of platinum and palladium, calculated respectively in kg/m 3 (g/L) and in relation to the volume of the support body, in washcoat layer A and washcoat layer B is equal; and the ratio of the concentrations of platinum and palladium in washcoat layer A to platinum and palladium in washcoat layer B, respectively in relation to the total mass of the respective washcoat layer, is 1:1 to 1:5, and wherein the quantity of cerium oxide in lower washcoat layer A exceeds the quantity of alkaline earth metal oxide or alkali metal oxide in lower washcoat layer A. 2. Nitrogen oxide storage catalyst according to claim 1 , wherein the washcoat layer B contains cerium oxide in a quantity of 22 to 120 kg/m 3 (22 to 120 g/L). 3. Nitrogen oxide storage catalyst according to claim 1 , wherein the washcoat layer A contains cerium oxide in a quantity of 110 to 160 kg/m 3 (110 to 160 g/L). 4. Nitrogen oxide storage catalyst according to claim 1 , wherein the total washcoat loading of the support body is 300 to 600 kg/m 3 (300 to 600 g/L) in relation to the volume of the support body. 5. Nitrogen oxide storage catalyst according to claim 4 , wherein the loading with washcoat layer A is 150 to 500 kg/m 3 (150 to 500 g/L), and the loading with washcoat layer B is 50 to 300 kg/m 3 (50 to 300 g/L), respectively in relation to the volume of the support body. 6. Nitrogen oxide storage catalyst according to claim 4 , wherein the loading with washcoat layer A is 250 to 300 kg/m 3 (250 to 300 g/L), and the loading with washcoat layer B is 50 to 150 kg/m 3 (50 to 150 g/L), respectively in relation to the volume of the support body. 7. Nitrogen oxide storage catalyst according to claim 1 , wherein the ratio of platinum to palladium is 4:1 to 18:1. 8. Nitrogen oxide storage catalyst according to claim 1 , wherein the ratio of platinum to palladium is 6:1 to 16:1. 9. Nitrogen oxide storage catalyst according to claim 1 wherein washcoat layer A and/or washcoat layer B contain rhodium. 10. Nitrogen oxide storage catalyst according to claim 9 , wherein rhodium is provided in quantities of 0.003 to 0.35 kg/m 3 (0.003 to 0.35 g/L) in relation to the volume of the support body. 11. Nitrogen oxide storage catalyst according to claim 1 , wherein the alkaline earth metal compound in washcoat layer A is magnesium oxide, barium oxide, and/or strontium oxide. 12. Nitrogen oxide storage catalyst composed of least two catalytically active washcoat layers on a support body, wherein a lower washcoat layer A contains cerium oxide in a quantity of 110 to 180 kg/m 3 (110 to 180 g/L) in relation to the volume of the support body, an alkaline earth metal compound and/or an alkali metal compound, as well as platinum and palladium; an upper washcoat layer B disposed atop the washcoat layer A contains cerium oxide, as well as platinum and palladium, and no alkali metal or alkaline earth metal compounds; the ratio of the cerium oxide in washcoat layer A to the cerium oxide in washcoat layer B is 1:1 to 5:1, wherein the total quantity of cerium oxide in washcoat layer A and washcoat layer B, calculated in kg/m 3 (g/L) and in relation to the volume of the support body, is 132 to 240 kg/m 3 (132 to 240 g/L); the ratio Pt:Pd in washcoat layer A and washcoat layer B Is equal, and the ratio Pt:Pd amounts to 2:1 to 20:1; the total quantity of platinum and palladium, calculated respectively in kg/m 3 (g/L) and in relation to the volume of the support body, in washcoat layer A and washcoat layer B is equal; and the ratio of the concentrations of platinum and palladium in washcoat layer A to platinum and palladium in washcoat layer B, respectively in relation to the total mass of the respective washcoat layer, is 1:1 to 1:5, and wherein the nitrogen oxide storage catalyst comprises a lower washcoat layer A that contains cerium oxide in a quantity of 100 to 160 kg/m 3 (100 to 160 g/L), platinum and palladium in a ratio of 10:1, as well as magnesium oxide and/or barium oxide: and an upper washcoat layer B that is disposed atop the washcoat layer A and contains no alkaline earth metal compound and no alkali metal compound, platinum and palladium in a ratio of 10:1, as well as cerium oxide in a quantity of 45 to 65 kg/m 3 (45 to 65 g/L), wherein washcoat layer A is provided in quantities of 250 to 350 kg/m (250 to 350 g/L), and washcoat layer B is provided in quantities of 80 to 130 kg/m (80 to 130 g/L), wherein the specification of quantity kg/m (g/L) respectively relates to the volume of the support body, and wherein the quantity of cerium oxide in lower washcoat layer A exceeds the quantity of alkaline earth metal oxide or alkali metal oxide in lower washcoat layer A. 13. Method of converting NOx in exhaust gases of motor vehicles that are operated with lean-burn engines, wherein the exhaust gas is guided over a nitrogen oxide storage catalyst composed of at least two catalytically active washcoat layers on a support body, wherein a lower washcoat layer A contains cerium oxide in a quantity of 110 to 180 kg/m 3 (110 to 180 g/L) in relation to the volume of the support body, an alkaline earth metal compound and/or an alkali metal compound, as well as platinum and palladium; an upper washcoat layer B disposed atop the washcoat layer A contains cerium oxide, as well as platinum and palladium, and no alkali metal or alkaline earth metal compounds; the ratio of the cerium oxide in washcoat layer A to the cerium oxide in washcoat layer B is equal to or greater than 2.27:1 up to 5:1, wherein the total quantity of cerium oxide in washcoat layer A and washcoat layer B, calculated in kg/m 3 (g/L) and in relation to the volume of the support body, is 132 to 240 kg/m 3 (132 to 240 g/L); the ratio Pt:Pd in washcoat layer A and washcoat layer B is equal, and the ratio Pt:Pd amounts to 2:1 to 20:1; the total quantity of platinum and palladium, calculated respectively in kg/m 3 (g/L) and in relation to the volume of the support body, in washcoat layer A and washcoat layer B is equal; and the ratio of the concentrations of platinum and palladium in washcoat layer A to platinum and palladium in washcoat layer B, respectively in relation to the total mass of the respective washcoat layer is 1:1 to 1:5, and wherein the quantity of cerium oxide in lower washcoat layer A exceeds the quantity of alkaline earth metal oxide or alkali metal oxide in lower washcoat layer A. 14. Nitrogen oxide storage catalyst according to claim 1 , wherein the alkaline earth metal compound in washcoat layer A is selected from the group consisting of magnesium oxide, barium oxide, strontium oxide,