Hybrid exhaust nozzle

What is claimed is: 1. A gas turbine engine comprising an engine core configured to discharge a first stream of pressurized air that is passed through the engine core along a central axis, a fan coupled to the engine core to be driven by the engine core, the fan configured to discharge a second stream of pressurized air and a third stream of pressurized air that are passed around the engine core, and an exhaust system coupled to the engine core, the exhaust system including (i) an inner duct arranged around the central axis to define an inner passageway arranged to receive the first stream and the second stream of pressurized air, (ii) an outer duct arranged radially outward of the inner duct around the central axis so that the inner duct and the outer duct cooperate to define an outer passageway arranged to receive the third stream of pressurized air, (iii) a plurality of aft adjustment flaps mounted to pivot relative to the inner duct, each of the aft adjustment flaps having an inner portion extending radially inward from the inner duct toward the central axis and an outer portion extending radially outward from the inner duct away from the central axis, and (iv) a plurality of forward adjustment flaps, each of the forward adjustment flaps having an aft end pivotally coupled to the outer portion of a corresponding aft adjustment flap and a forward end mounted to the inner duct to slide relative to the inner duct. 2. The gas turbine engine of claim 1 , wherein (i) the aft adjustment flaps are mounted to pivot relative to the inner duct between a constricted position in which the aft adjustment flaps close down a first throat defined between the outer portions of the aft adjustment flaps and the outer duct to restrict the third stream of pressurized air from passing through the outer passageway and an unconstricted position in which the aft adjustment flaps open the first throat to allow the third stream of pressurized air to pass more freely through the outer passageway, (ii) the aft adjustment flaps close down a second throat defined between the inner portions of the aft adjustment flaps to restrict the first and second streams of pressurized air from passing through the inner passageway when the aft adjustment flaps are in the constricted position, and (iii) the aft adjustment flaps open the second throat to allow the first and second streams of pressurized air to pass more freely through the inner passageway when the aft adjustment flaps are in the unconstricted position. 3. The gas turbine engine of claim 2 , wherein a first angle is defined between the inner duct and the outer portions of the aft adjustment flaps when the aft adjustment flaps are in the constricted position and a second angle is defined between the inner duct and the outer portions of the aft adjustment flaps when the aft adjustment flaps are in the unconstricted position that is less than the first angle. 4. The gas turbine of claim 2 , wherein movement of the aft adjustment flaps between the constricted position and the unconstricted position causes the forward ends of the forward adjustment flaps to slide relative to the inner duct between (i) an aft position along the central axis and (ii) a forward position along the central axis that is forward of the aft position. 5. The gas turbine engine of claim 2 , wherein (i) the exhaust system further comprises a divergent section coupled to the outer duct and arranged to extend away from the outer duct toward the central axis and a plurality of divergent flaps coupled to the divergent section so that the divergent flaps extend aft of the inner portions of the aft adjustment flaps away from the central axis and (ii) the inner portions of the aft adjustment flaps and the divergent flaps cooperate to define a third throat that is positioned aft of the first throat along the central axis. 6. The gas turbine engine of claim 5 , wherein (i) movement of the aft adjustment flaps to the unconstricted position closes down the third throat to restrict the third stream of pressurized air from passing to the divergent section and (ii) movement of the aft adjustment flaps to the constricted position opens the third throat to allow the third stream of pressurized air to pass more freely to the divergent section. 7. The gas turbine engine of claim 6 , wherein the divergent flaps are mounted to pivot relative to the divergent section between (i) a constricted position in which the divergent flaps close down the third throat to restrict the third stream of pressurized air from passing to the divergent section and (ii) an unconstricted position in which the divergent flaps open the third throat to allow the third stream of pressurized air to pass more freely to the divergent section. 8. The gas turbine engine of claim 5 , wherein (i) the outer duct terminates at an outer duct outlet having a substantially circular cross section and (ii) the divergent section includes a divergent section inlet fluidly coupled to the outer duct outlet that has a first substantially quadrilateral cross section. 9. The gas turbine engine of claim 8 , wherein the divergent section terminates at a exit area positioned aft of the divergent section inlet along the central axis that has a second substantially quadrilateral cross section different from the first substantially quadrilateral cross section. 10. The gas turbine engine of claim 9 , wherein (i) the outer and inner ducts are shaped to conduct the first, second, and third streams of pressurized air substantially axisymmetrically relative to the central axis to the divergent section inlet and (ii) the divergent section is shaped to conduct the first, second, and third streams of pressurized air substantially two-dimensionally relative to the central axis from the divergent section inlet to the exit area. 11. An exhaust system for a gas turbine engine, the exhaust system comprising a inner duct arranged around a central axis of the gas turbine engine, the inner duct defining an inner passageway arranged to receive a first stream of pressurized air discharged from an engine core of the gas turbine engine and a second stream of pressurized air discharged from a fan of the gas turbine engine and passed around the engine core, an outer duct arranged radially outward of the inner duct around the central axis of the gas turbine engine, the outer duct cooperating with the inner duct to define an outer passageway arranged to receive a third stream of pressurized air discharged from the fan of the gas turbine engine and passed around the engine core, a plurality of aft adjustment flaps mounted to pivot relative to the inner duct, each of the aft adjustment flaps having an inner portion extending radially inward from the inner duct toward the central axis and an outer portion extending radially outward from the inner duct away from the central axis, and a plurality of forward adjustment flaps positioned forward of the aft adjustment flaps along the central axis, each of the forward adjustment flaps having an aft end pivotally coupled to the outer portion of a corresponding aft adjustment flap and a forward end mounted to the inner duct to slide relative to the inner duct. 12. The exhaust system of claim 11 , further comprising a divergent section coupled to the outer duct and arranged to extend away from the outer duct toward the central axis and a plurality of divergent flaps coupled to the divergent section so that the divergent flaps extend aft of the inner portions of the aft adjustment flaps away from the central axis, wherein (i) the inner portions of the aft adjustment flaps and the divergent flaps cooperate to define a first throat arranged to receive the third st