Dual-acting valve enabled catalyst bypass

What is claimed is: 1. An internal combustion engine comprising: a cylinder head with an exhaust manifold configured to supply exhaust gas through a main exhaust outlet to a main exhaust aftertreatment system having a main catalytic converter, a main outlet duct configured to receive exhaust gas flow from the exhaust manifold and define the main exhaust outlet: a bypass passage in fluid communication with the exhaust manifold via a bypass port; a bypass catalytic converter disposed within the bypass passage; and a dual-acting valve assembly configured to move between a first position that seals the bypass port, and a second position that seals the main exhaust outlet, wherein during cold start, long idle, and/or low main catalytic converter temperature conditions, the dual-active valve assembly is moved to the second position to direct exhaust flow through the bypass passage and the bypass catalytic converter to reduce emissions, wherein the main outlet duct includes a recessed first valve seat formed around the bypass port, and wherein in the first position, the dual-acting valve assembly is configured to seat flush within the recessed first valve seat to facilitate preventing obstruction of exhaust gas flow within the main outlet duct; wherein the bypass passage is integrally formed within the cylinder head, and wherein the bypass catalytic converter is disposed within the bypass passage within the cylinder head. 2. The engine of claim 1 , wherein the bypass port is formed in the main outlet duct. 3. The engine of claim 1 , wherein the main outlet duct is a separate and distinct component configured to couple to the cylinder head. 4. The engine of claim 3 , wherein the main outlet duct is a turbine inlet. 5. The engine of claim 1 , wherein the main outlet duct further includes a recessed second valve seat formed around the main exhaust outlet, and wherein in the second position, the dual-acting valve assembly is configured to seat flush within the recessed second valve seat to facilitate preventing obstruction of exhaust gas flow through the bypass port. 6. The engine of claim 1 , wherein the dual-acting valve assembly includes a valve door coupled to a valve shaft. 7. The engine of claim 6 , wherein the valve shaft is rotatably seated within a bore formed in the main outlet duct, the valve shaft rotatable to move the valve door to the first position to seal the bypass port, and the second position to seal the main exhaust outlet. 8. The engine of claim 7 , further comprising an actuator assembly operably coupled to the valve shaft to rotate the valve shaft within the bore. 9. The engine of claim 8 , further comprising a turbocharger, wherein the actuator assembly is coupled to the turbocharger, and wherein an actuator link is operably coupled between the actuator assembly and the valve shaft for selective rotation thereof. 10. The engine of claim 1 , wherein the bypass port is formed in a collector portion of the exhaust manifold. 11. The engine of claim 1 , further comprising a water jacket formed in the cylinder head proximate a bypass catalyst conduit holding the bypass catalytic converter, wherein the water jacket is configured to circulate a coolant to provide cooling to the bypass catalytic converter.