Distributed control of selective catalytic reduction systems

The invention claimed is: 1. A vehicle exhaust emission control system, comprising: an SCR catalyst arranged in an engine exhaust passage downstream of a reductant injector; a controller comprising a processor and a non-transitory, computer-readable medium storing instructions executable by the processor to: divide an embedded virtual model of an SCR catalyst stored in non-transitory memory of the controller into a plurality of radial zones; determine a reductant storage setpoint for each zone based on a volume and estimated temperature of the zone; and adjust a radial distribution of reductant in the SCR catalyst, based on a comparison of a current level of reductant stored in each zone with the reductant storage setpoint for that zone, by adjusting a spray pattern of reductant injected upstream of the SCR catalyst. 2. The system of claim 1 , wherein adjusting the spray pattern of reductant injected upstream of the SCR catalyst comprises adjusting one or more of reductant injection pressure, reductant injection quantity, and reductant injection timing. 3. The system of claim 1 , further comprising instructions stored in the medium which are executable by the processor to: further divide the embedded virtual model of the SCR catalyst into a plurality of axial zones; determine a reductant storage setpoint for each axial zone based on a volume and estimated temperature of the zone; and adjust an axial distribution of reductant in the SCR catalyst, based on a comparison of a current level of reductant stored in each axial zone with the reductant storage setpoint for that zone, by adjusting temperature of exhaust gas entering the SCR catalyst and/or adjusting a concentration of NO x in the exhaust gas entering SCR catalyst. 4. The system of claim 3 , wherein the estimated temperature of each radial and axial zone is determined based on one or more of a thermal model stored in the memory, an ambient temperature, and a projected heat loss of the SCR catalyst to its surroundings. 5. The system of claim 1 , wherein dividing the virtual model of the SCR catalyst into a plurality of radial zones comprises dividing the virtual model of the SCR catalyst into an inner radial zone and at least one outer radial zone. 6. The system of claim 5 , wherein a radius of a cross-section of the inner radial zone and a radial thickness of each outer radial zone is defined based on one or more of a thermal model of the SCR catalyst stored in the computer-readable medium, an ambient temperature, and a projected heat loss of the SCR catalyst to its surroundings. 7. The system of claim 5 , wherein there is exactly one outer radial zone in the virtual model of the SCR catalyst, wherein the inner radial zone is modeled as a cylinder, and wherein the outer radial zone is modeled as a hollow cylinder, and wherein an inner circumference of the outer radial zone is coextensive with a circumference of the inner radial zone and forms a boundary between the inner and outer radial zones in the model. 8. A method for a vehicle engine emission control system, comprising: comparing an estimated spatial distribution of reductant stored in an SCR catalyst with a desired spatial distribution of reductant stored in the catalyst; if radial adjustment of the spatial distribution is desired, adjusting a pressure at which reductant is injected into the SCR catalyst; if axial adjustment of the spatial distribution is desired, adjusting exhaust gas temperature and/or NO x concentration. 9. The method of claim 8 , further comprising, if axial adjustment of the spatial distribution is desired, determining whether the spatial distribution is skewed towards an upstream side or a downstream side of the SCR catalyst with respect to the direction of exhaust gas flow; if the spatial distribution is skewed towards the upstream side of the SCR catalyst, actively increasing a temperature of the exhaust gas entering the SCR catalyst; and if the spatial distribution is skewed towards the downstream side of the SCR catalyst, actively increasing a concentration of NO x in the exhaust gas entering the SCR catalyst. 10. The method of claim 9 , wherein actively increasing the temperature of the exhaust gas entering the SCR catalyst comprises adjusting engine operating conditions and/or activating a glow plug or burner arranged in the emission control system upstream of the SCR catalyst. 11. The method of claim 9 , wherein actively increasing the concentration of NO x in exhaust gas entering the SCR catalyst comprises one or more of retarding spark timing, decreasing engine air-fuel ratio, and decreasing an EGR rate. 12. The method of claim 8 , further comprising increasing an amount of reductant injected into the SCR catalyst for a duration after adjusting the NO x concentration. 13. A method for a vehicle emission control system, comprising: with a controller, modeling an expected distribution of stored reductant among a plurality of axial zones and a plurality of radial zones of an SCR catalyst arranged in an engine exhaust passage and comparing the expected distribution with a reductant storage setpoint of each zone; based on the comparison, adjusting a radial storage location of reductant by adjusting a spray pattern of reductant injected upstream of the SCR catalyst; and adjusting an axial storage location of reductant by adjusting temperature and NO x concentration of exhaust gas entering SCR catalyst. 14. The method of claim 13 , wherein the model of the distribution of stored reductant stored among the zones is based on one or more of a thermal model of the SCR catalyst stored in non-transitory memory of the controller, ambient temperature, and projected heat loss of the SCR catalyst to its surroundings. 15. The method of claim 13 , wherein adjusting the spray pattern of reductant injected upstream of the SCR catalyst comprises adjusting one or more of injection pressure, injection quantity, and injection timing. 16. The method of claim 15 , wherein the plurality of radial zones of the SCR catalyst comprises an inner radial zone and an outer radial zone, the method further comprising: decreasing reductant injection pressure if an amount of reductant stored in the outer radial zone is greater than or equal to the reductant storage setpoint of the outer radial zone and an amount of reductant stored in the inner radial zone is less than the reductant storage setpoint of the inner radial zone; and increasing reductant injection pressure if the amount of reductant stored in the outer radial zone is less than the reductant storage setpoint of the outer radial zone and the amount of reductant stored in the inner radial zone is greater than or equal to the reductant storage setpoint of the inner radial zone. 17. The method of claim 16 , further comprising: maintaining reductant injection pressure at a nominal level and decreasing a quantity of reductant injected if the amount of reductant stored in the outer radial zone is greater than or equal to the reductant storage setpoint of the outer radial zone and the amount of reductant stored in the inner radial zone is greater than or equal to the reductant storage setpoint of the inner radial zone; and maintaining reductant injection pressure at the nominal level and increasing the quantity of reductant injected if the amount of reductant stored in the outer radial zone is less than the reductant storage setpoint of the outer radial zone and the amount of reductant stored in the inner radial zone is less than the reductant storage setpoint of the inner radial zone.