Underflow selective catalytic reduction steady state ammonia slip detection with positive perturbation

What is claimed is: 1. An emissions control system for treating exhaust gas in a motor vehicle including an internal combustion engine, the emissions control system comprising: a selective catalytic reduction (SCR) device; an underflow selective catalytic reduction (UFSCR) device operably connected downstream of and in fluid communication with the SCR device; a first NOx sensor operably connected to and in fluid communication with the exhaust gas downstream of the SCR device; a second NOx sensor operably connected to and in fluid communication with the exhaust gas downstream of the UFSCR device; a controller operably connected to the SCR device, the first NOx sensor, the second NOx sensor, the controller configured to perform reductant slip detection method by: determining if the SCR device is in a steady state operating condition with a steady state reductant injection; under selected conditions, perturbing a reductant injection corresponding the steady state; the perturbation of the reductant injection having a selected magnitude and a selected duration; measuring a NOx value from the first NOx sensor corresponding to the steady state; measuring a NOx value from the second NOx sensor corresponding to the steady state; measuring a NOx value from the first NOx sensor resultant from the perturbing the reductant injection and computing a gradient in the NOx value resultant from the perturbing the reductant injection relative to the NOx value measured at steady state from the first NOx sensor; measuring the NOx value from the second NOx sensor resultant from the perturbing the reductant injection and computing a gradient in the NOx value resultant from the perturbing the reductant injection relative to the NOx value measured from the second NOx sensor at steady state; comparing the gradient of the NOx value from the second NOx sensor resultant from the perturbing with the gradient of the NOx value from the first NOx sensor resultant from the perturbing; and if the gradient NOx value from the first NOx sensor resultant from the perturbing is within a selected range of the gradient of the NOx value from the second NOx sensor resultant from the perturbing identifying poor efficiency operation for the engine and setting an estimated reductant storage at zero, otherwise if the gradient NOx value from the second NOx sensor resultant from the perturbing exceeds a selected threshold, identifying a reductant slip condition and setting the estimated reductant storage at maximum, otherwise, making no corrections in estimated reductant storage. 2. The emissions control system of claim 1 , further including a temperature sensor operably connected to and in fluid communication with the exhaust gas, the temperature sensor in operable communication with the controller. 3. The emissions control system of claim 2 , further including a third NOx sensor operably connected to and in fluid communication with the exhaust gas, the third NOx disposed upstream of the SCR device and in operable communication with the controller. 4. The emissions control system of claim 3 , further including the controller executing a method further including: computing a gradient of a temperature of the SCR device and a gradient of a NOx value measured by the first NOx sensor; and comparing a steady state NOx value from the third NOx sensor with a predicted steady state NOx value. 5. The emissions control system of claim 4 , wherein the selected conditions include identifying the SCR devices as at steady state if the gradient of a temperature of the SCR device is less than a third selected threshold value and a gradient of the NOx measured by the another NOx sensor is less than a fourth selected threshold value. 6. The emissions control system of claim 4 , wherein the predicted NOx value is based on a chemical model of the SCR device. 7. The emissions control system of claim 4 , further including the controller executing a method including, adapting a reductant dosing rate of the SCR device according to the comparing. 8. The emissions control system of claim 1 , wherein the first NOx sensor is located downstream from the SCR device. 9. The emissions control system of claim 1 , wherein the second NOx sensor is located downstream from the UFSCR device. 10. The emissions control system of claim 1 wherein the selected range is based on at least a temperature of the UFSCR device and a flow of the exhaust gas. 11. The emissions control system of claim 1 , wherein at least one of the selected magnitude and selected duration of the perturbing a reductant injection is based on at least one of a magnitude of the steady state reductant injection, an exhaust flow and a temperature. 12. A method for treating exhaust gas emitted by an internal combustion engine, configured to perform a selective catalytic reduction (SCR) of exhaust gas in a controller operably connected to a first NOx sensor and second NOx sensor, each disposed in the exhaust gas, the controller configured to execute the method for ammonia slip detection comprising: determining if the SCR device is in a steady state operating condition with a steady state reductant injection; under selected conditions, perturbing a reductant injection corresponding the steady state; the perturbation of the reductant injection having a selected magnitude and a selected duration; measuring a NOx value from the first NOx sensor corresponding to the steady state; measuring a NOx value from the second NOx sensor corresponding to the steady state; measuring a NOx value from the first NOx sensor resultant from the perturbing the reductant injection and computing a gradient in the NOx value resultant from the perturbing the reductant injection relative to the NOx value measured at steady state from the first NOx sensor; measuring the NOx value from the second NOx sensor resultant from the perturbing the reductant injection and computing a gradient in the NOx value resultant from the perturbing the reductant injection relative to the NOx value measured from the second NOx sensor at steady state; comparing the gradient of the NOx value from the second NOx sensor resultant from the perturbing with the gradient of the NOx value from the first NOx sensor resultant from the perturbing; and if the gradient NOx value from the first NOx sensor resultant from the perturbing is within a selected range of the gradient of the NOx value from the second NOx sensor resultant from the perturbing identifying poor efficiency operation for the engine and setting an estimated reductant storage at zero, otherwise if the gradient NOx value from the second NOx sensor resultant from the perturbing exceeds a selected threshold, identifying a reductant slip condition and setting the estimated reductant storage at maximum, otherwise, making no corrections in estimated reductant storage. 13. The method of claim 12 , further including operably connecting a temperature sensor with the controller, the temperature sensor in fluid communication with the exhaust gas. 14. The method of claim 13 , further including operably connecting a third NOx sensor with the controller, the third NOx disposed upstream of the SCR device and in fluid communication with the exhaust gas. 15. The method of claim 14 , further including the controller executing a method comprising: computing a gradient of a temperature of the SCR device and a gradient of a NOx value measured by the first NOx sensor; and comparing a steady state NOx value from the third NOx sensor with a predicted steady state NOx value. 16. The method of claim 15 , wherei