SYSTEMS AND METHODS FOR ON-BOARD MONITORING OF A PASSIVE NOx ADSORPTION CATALYST

1 . A method, comprising: indicating degradation of a passive NOx adsorption catalyst (PNA) based on an amount of nitrogen oxides (NOx) measured downstream of the PNA during an overrun event that occurs after an exhaust gas temperature measured upstream of the PNA reaches a lower threshold temperature and while a modeled stored NOx value is greater than a lower threshold value. 2 . The method of claim 1 , wherein the indicating degradation of the PNA is responsive to the exhaust gas temperature measured upstream of the PNA being within a threshold temperature range defined by the lower threshold temperature and an upper threshold temperature, and wherein the modeled stored NOx value is based in part on the exhaust gas temperature measured upstream of the PNA. 3 . The method of claim 1 , wherein the amount of NOx measured downstream of the PNA during the overrun event is an average amount of NOx calculated from a plurality of NOx measurements recorded after an overrun delay. 4 . The method of claim 3 , wherein a duration of the overrun delay is determined based on at least one of engine speed and engine airflow. 5 . The method of claim 3 , wherein the plurality of NOx measurements are recorded during a single overrun event or recorded during a plurality of overrun events. 6 . The method of claim 1 , wherein the indicating degradation of the PNA based on the amount of NOx measured downstream of the PNA during the overrun event is responsive to the amount of NOx being less than a threshold amount of NOx. 7 . The method of claim 6 , wherein the threshold amount of NOx is determined based on an average exhaust gas temperature measured upstream of the PNA during the overrun event and is independent of an amount of NOx input into the PNA. 8 . The method of claim 1 , further comprising: responsive to the indicating degradation of the PNA, adjusting an engine operating parameter, including one or more of an exhaust gas recirculation amount and a fuel injection timing. 9 . The method of claim 1 , further comprising operating in the overrun event, including stopping fuel injection to the engine, after the exhaust gas temperature measured upstream of the PNA reaches the lower threshold temperature and while the modeled stored NOx value is greater than the lower threshold value, and during the operating in the overrun event: measuring the amount of NOx downstream of the PNA; and indicating degradation of the PNA based on the measured amount of NOx. 10 . A method, comprising: operating an engine in a first condition while an exhaust gas temperature is above a lower threshold temperature and below an upper threshold temperature and a modeled stored NOx value is above a lower threshold value; and in response to operating the engine in the first condition: measuring an amount of NOx released by a passive NOx adsorption catalyst (PNA); and indicating a degraded NOx storage capacity or a non-degraded NOx storage capacity of the PNA based on the measured amount of NOx. 11 . The method of claim 10 , wherein the measuring the amount of NOx released by the PNA is via a NOx sensor positioned downstream of the PNA and during an overrun event, and the indicating the degraded NOx storage capacity or the non-degraded NOx storage capacity based on the measured amount of NOx comprises: indicating the degraded NOx storage capacity in response to the measured amount of NOx being less than a threshold; and indicating the non-degraded NOx storage capacity in response to the measured amount of NOx being greater than the threshold. 12 . The method of claim 11 , wherein the threshold is determined based on the exhaust gas temperature during the overrun event. 13 . The method of claim 11 , further comprising: responsive to the indicating the degraded NOx storage capacity, adjusting an operating parameter of the engine, including one or more of an engine dilution, a timing of fuel injections to the engine, and a number of the fuel injections, during a subsequent start of the engine; and responsive to the indicating the non-degraded NOx storage capacity, maintaining the operating parameter of the engine during the subsequent start of the engine. 14 . The method of claim 10 , further comprising: in response to at least one the exhaust gas temperature decreasing below the lower threshold temperature, the exhaust gas temperature exceeding the upper threshold temperature, and the modeled stored NOx value decreasing below the lower threshold value, operating the engine in a second condition where the degraded NOx storage capacity or the non-degraded NOx storage capacity is not indicated. 15 . A system, comprising: an engine configured to combust fuel and air; a passive NOx adsorption catalyst coupled to an exhaust passage of the engine, the passive NOx adsorption catalyst having a NOx storage capacity; and a controller storing executable instructions in non-transitory memory that, when executed, cause the controller to: measure an amount of NOx released from the passive NOx adsorption catalyst in response to an exhaust gas temperature being within a threshold temperature range, a modeled stored NOx value being greater than a lower threshold value, and the engine operating during a fuel cut condition where no fuel is injected into the engine; and indicate degradation of the passive NOx adsorption catalyst in response to the measured amount of NOx released being below a threshold NOx value. 16 . The system of claim 15 , further comprising: a selective catalytic reduction (SCR) catalyst coupled to the exhaust passage downstream of the passive NOx adsorption catalyst; only one NOx sensor arranged in the exhaust passage, the only one NOx sensor positioned downstream of the passive NOx adsorption catalyst and upstream of the SCR catalyst; and an exhaust gas temperature sensor coupled upstream of the passive NOx adsorption catalyst; and wherein the instructions that cause the controller to measure the amount of NOx released from the passive NOx adsorption catalyst in response to the exhaust gas temperature being within the threshold temperature range, the modeled stored NOx value being greater than the lower threshold value, and the engine operating during the fuel cut condition where no fuel is injected into the engine include further instructions stored in non-transitory memory that, when executed, cause the controller to: record NOx measurements from an output of the only one NOx sensor and exhaust gas temperature measurements from an output of the exhaust gas temperature sensor after a first threshold duration has elapsed since a beginning of the fuel cut condition; stop recording the NOx measurements and the exhaust gas temperature measurements in response to a second threshold duration elapsing during the fuel cut condition or in response to an end of the fuel cut condition; calculate an average NOx value from the recorded NOx measurements and an average exhaust gas temperature value from the recorded exhaust gas temperature measurements; and determine the threshold NOx value based on the average exhaust gas temperature value. 17 . The system of claim 16 , wherein the instructions that cause the controller to indicate degradation of the passive NOx adsorption catalyst in response to the measured amount of NOx released being below the threshold NOx value include further instructions stored in non-transitory memory that, when executed, cause the controller to: indicate degradation of the NOx storage capacity of the passive NOx absorption catalyst in response to the average