Perovskite oxide compounds for use in exhaust aftertreatment systems

What is claimed is: 1. A method comprising: supplying a combustion source with air and fuel at an air to fuel mass ratio that can be selectively varied to produce a lean mixture of air and fuel, in which the air to fuel mass ratio is above stoichiometry, and a rich mixture of air and fuel, in which the air to fuel mass ratio is at or below stoichiometry, the combustion source being coupled to an exhaust aftertreatment system that comprises a NO X oxidation catalyst that includes perovskite oxide particles, a NO X storage catalyst, and a NO X reduction catalyst wherein the NO X oxidation catalyst is intermingled with the NO X storage catalyst; combusting the lean mixture of air and fuel at the combustion source to produce an oxygen-rich exhaust flow that comprises nitrogen oxide gases (NO X ) including NO and NO 2 ; passing the oxygen-rich exhaust flow through the exhaust aftertreatment to (1) oxidize NO to NO 2 over the NO X oxidation catalyst and (2) store NO X as a nitrate species at the NO X storage catalyst; combusting the rich mixture of air and fuel at the combustion source to produce an oxygen-depleted exhaust flow; and passing the oxygen-depleted exhaust flow through the exhaust aftertreatment system to (1) release NO X from the NO X storage catalyst and (2) reduce NO X to N 2 over the NO X reduction catalyst. 2. The method according to claim 1 , wherein the exhaust aftertreatment system comprises a first catalyst material and a second catalyst material positioned downstream from the first catalyst material relative to a flow direction through the exhaust aftertreatment system, the first catalyst material comprising the perovskite oxide particles, the second catalyst material comprising the NO X reduction catalyst, the first catalyst material comprising the NO X storage catalyst, and either the first catalyst material or the second catalyst material comprising palladium particles. 3. The method according to claim 2 , wherein the perovskite oxide particles comprise at least one of LaCoO 3 , LaMnO 3 , LaFeO 3 , La 0.9 Sr 0.1 CoO 3 , La 0.9 Sr 0.1 MnO 3 , or La 0.9 Sr 0.1 FeO 3 , wherein the NO X storage catalyst comprises at least one of BaO, BaCO 3 , or K 2 CO 3 particles, wherein the NO X reduction catalyst comprises rhodium particles. 4. The method according to claim 2 , wherein the exhaust aftertreatment system further comprises a third catalyst material located downstream from the second catalyst material relative to the flow direction, the third catalyst material comprising particles of a microporous molecular sieve material that can catalytically reduce NO X with an absorbed reductant in the presence of oxygen, the microporous molecular sieve material comprising at least one of a base metal ion-substituted zeolite, a base metal oxide, or a base metal ion-substituted silicoaluminophosphate. 5. The method according to claim 4 , further comprising: passing the oxygen-rich exhaust flow through the exhaust aftertreatment system along the flow direction to selectively reduce NO X in the presence of absorbed ammonia and oxygen at the third catalyst material; and passing the oxygen-depleted exhaust flow through the exhaust aftertreatment system along the flow direction to form ammonia over the palladium and/or NO X reduction particles and supplying the ammonia to the third catalyst material for absorption therein. 6. A method comprising: supplying a multi-cylinder internal combustion engine with air and fuel at an air to fuel mass ratio that can be selectively varied to produce a lean mixture of air and fuel, in which the air to fuel mass ratio is above stoichiometry, and a rich mixture of air and fuel, in which the air to fuel mass ratio is at or below stoichiometry, the engine being coupled to an exhaust aftertreatment system that comprises a first catalyst material and a second catalyst material, the second catalyst material being located downstream from the first catalyst material relative to a flow direction, the first catalyst material comprising a NO X oxidation catalyst that includes perovskite oxide particles, the second catalyst material comprising a NO X reduction catalyst, and the first catalyst material comprising a NO X storage catalyst; combusting the lean mixture of air and fuel at the engine to produce an oxygen-rich exhaust flow that comprises nitrogen oxide gases (NO X ) including NO and NO 2 ; passing the oxygen-rich exhaust flow through the exhaust aftertreatment system along the flow direction to (1) oxidize NO to NO 2 over the NO X oxidation catalyst at the first catalyst material and (2) store NO 2 at the NO X storage catalyst; combusting the rich mixture of air and fuel at the engine to produce an oxygen-depleted exhaust flow; and passing the oxygen-depleted exhaust flow through the exhaust aftertreatment system along the flow direction to (1) release NO X from the NO X storage catalyst and (2) reduce NO X to N 2 over the NO X reduction catalyst at the second catalyst material. 7. The method according to claim 6 , wherein the first catalyst material comprises a first carrier material on which the NO X oxidation catalyst is dispersed, wherein the second catalyst material comprises a second carrier material on which the NO X storage catalyst and the NO X reduction catalyst are dispersed, and wherein the first and second carrier materials comprise at least one of a CeO 2 —ZrO 2 material, alumina, or a zeolite. 8. The method according to claim 6 , wherein the first catalyst material comprises a first carrier material on which the NO X oxidation catalyst and the NO X storage catalyst are dispersed, wherein the second catalyst material comprises a second carrier material on which the NO X reduction catalyst is dispersed, and wherein the first and second carrier materials comprise at least one of a CeO 2 —ZrO 2 material, alumina, or a zeolite. 9. The method according to claim 6 , wherein the perovskite oxide particles comprise at least one of LaCoO 3 , LaMnO 3 , LaFeO 3 , La 0.9 Sr 0.1 CoO 3 , La 0.9 Sr 0.1 MnO 3 , or La 0.9 Sr 0.1 FeO 3 , wherein the NO X storage catalyst comprises alkali or alkaline earth metal oxide particles, and wherein the NO X reduction catalyst comprises rhodium particles. 10. The method according to claim 9 , wherein the first and second catalyst materials are carried on a flow-through support body that comprises flow-through channels, wherein are perovskite oxide particles are present in the first catalyst material in an amount that ranges from about 50 g to about 150 g per liter of available flow volume through the flow-through support body, wherein the rhodium particles are present in an amount that ranges from about 0.10 g to about 0.30 g per liter of available flow volume through the flow-through support body, and wherein the alkali or alkaline earth metal oxide particle are present in the first or second catalyst material in an amount that ranges from about 10 g to about 50 g per liter of available flow volume through the flow-through support body. 11. The method according to claim 6 , wherein the exhaust aftertreatment system further comprises a third catalyst material located downstream from the second catalyst material relative to the flow direction, the third catalyst material comprising a microporous molecular seive material that can catalytically reduce NO X with an absorbed reductant in the presence of oxygen, and wherein the microporous molecular sieve material comprises particles of at least one of a base metal ion-substituted zeolite, a base metal oxide, or a base metal ion-substituted silicoaluminophosphate. 12. The method according to claim 11 , wherein at least one of the