Dual function air diverter and variable area fan nozzle

What is claimed is: 1. A fan air diverter for a gas turbine engine having at least an inner cowl, an outer nacelle and an annular air-oil cooler, the fan air diverter comprising: a nozzle flap disposed circumferentially about the inner cowl and coaxially adjacent to the annular air-oil cooler, the nozzle flap having a leading edge that is pivotally hinged to the inner cowl such that the nozzle flap forms a portion of an inner cowl surface adjacent to the air-oil cooler, the nozzle flap being selectively movable relative to the annular air-oil cooler between an open position and a closed position, wherein the nozzle flap is axially positioned at a fore of the annular air-oil cooler, and wherein the nozzle flap has a trailing edge that is movable between the open position and the closed position relative to an inlet of the annular air-oil cooler; and an actuation system assembly operatively coupling the nozzle flap to the inner cowl, the actuation system assembly being configured to actuate the nozzle flap between the open position and the closed position, wherein actuation of the nozzle flap between the open position and the closed position increases and decreases a fan nozzle area defined between the inner cowl and the outer nacelle. 2. The fan air diverter of claim 1 , wherein the nozzle flap comprises of two or more arcuate segments circumferentially disposed about the surface of the inner cowl, and about an inner fixed structure at the fore of a core cowl. 3. The fan air diverter of claim 1 , wherein the nozzle flap, in the open position, enables fan airflow toward a corresponding portion of the annular air-oil cooler and provides an increased fan nozzle area, and in the closed position, diverts fan airflow away from a corresponding portion of the annular air-oil cooler and provides a decreased fan nozzle area. 4. A fan air diverter for a gas turbine engine having at least an inner cowl, an outer nacelle and an annular air-oil cooler, the fan air diverter comprising: a nozzle flap disposed circumferentially about the inner cowl and coaxially adjacent to the annular air-oil cooler, the nozzle flap having a leading edge and a trailing edge, wherein the trailing edge is pivotally hinged to the inner cowl such that the nozzle flap forms a portion of an inner cowl surface adjacent to the air-oil cooler, the nozzle flap being selectively movable relative to the annular air-oil cooler between an open position and a closed position, wherein the nozzle flap is axially positioned aft of the annular oil cooler, and the leading edge is movable between the open position and the closed position relative to an outlet of the annular oil cooler; and an actuation system assembly operatively coupling the nozzle flap to the inner cowl, the actuation system assembly being configured to actuate the nozzle flap between the open position and the closed position, wherein actuation of the nozzle flap between the open position and the closed position increases and decreases a fan nozzle area defined between the inner cowl and the outer nacelle, wherein the actuator assembly comprises: at least one sync ring circumferentially disposed between a low pressure compressor case and the nozzle flap, the sync ring being rotatable between a first angular position and a second angular position about the engine axis; and a plurality of idler links radially coupling the sync ring to the nozzle flaps, the idler links being pivotally configured such that rotation of the sync ring to the first angular position moves the nozzle flap to the open position, and rotation of the sync ring to the second angular position moves the nozzle flap to the closed position. 5. The fan air diverter of claim 4 , wherein the actuation system assembly comprises a plurality of roller guides disposed between the sync ring and an outer surface of the low pressure compressor case so as to enable rotation of the sync ring about a central axis of the gas turbine engine. 6. The fan air diverter of claim 4 , wherein the actuation system assembly comprises a guide ring circumferentially disposed between the sync ring and an outer surface of the low pressure compressor case, the guide ring being rigidly coupled to an assembly mounted to the gas turbine engine, the sync ring being slidably rotatable about the guide ring via a plurality of bumpers disposed therebetween. 7. An oil cooling assembly for a gas turbine engine having an inner cowl and an outer nacelle, comprising: an annular air-oil cooler circumferentially disposed about the inner cowl, the annular air-oil cooler including an integral annular oil tank and a plurality of cooling fins radially extending therefrom, the cooling fins being disposed in at least partial communication with a fan duct and nozzle; and a fan air diverter circumferentially disposed about the inner cowl and coaxially adjacent to the cooling fins, wherein the fan air diverter comprises a nozzle flap pivotally hinged to the inner cowl such that the nozzle flap forms a portion of an inner cowl surface adjacent to the air-oil cooler, the nozzle flap having a leading edge and a trailing edge and being selectively movable relative to the cooling fins between an open position and a closed position, wherein actuation of the nozzle flap between the open position and the closed position increases and decreases a fan nozzle area defined between the inner cowl and the outer cowl, wherein the nozzle flap is axially positioned at a fore of the cooling fins, and the trailing edge is movable between the open position and the closed position relative to an inlet of the annular air-oil cooler; and an actuation system assembly, the actuation system assembly being configured to selectively move the nozzle flap between an open position and a closed position relative to the cooling fins, wherein the actuation assembly comprises: at least one sync ring circumferentially disposed between an outer surface of an associated low pressure compressor case and the nozzle flap, the sync ring being rotatable between a first angular position and a second angular position about a central axis of the gas turbine engine; and a plurality of idler links radially coupling the sync ring to the nozzle flap, the idler links being pivotally configured such that rotation of the sync ring to the first angular position moves the nozzle flap to the open position, and rotation of the sync ring to the second angular position moves the nozzle flap to the closed position. 8. The oil cooling assembly of claim 7 , wherein the nozzle flap is a fore nozzle flap and the oil cooling assembly further comprises an aft nozzle flap pivotally disposed adjacent to the cooling fins at an outlet of the annular oil cooler, each of the fore nozzle flap and the aft nozzle flap being independently actuatable so as to modulate fan airflow and fan nozzle area. 9. An oil cooling assembly for a gas turbine engine having an inner cowl and an outer nacelle, comprising: an annular air-oil cooler circumferentially disposed about the inner cowl, the annular air-oil cooler including an integral annular oil tank and a plurality of cooling fins radially extending therefrom, the cooling fins being disposed in at least partial communication with a fan duct and nozzle; and a fan air diverter circumferentially disposed about the inner cowl and coaxially adjacent to the cooling fins, wherein the fan air diverter comprises a nozzle flap pivotally hinged to the inner cowl such that the nozzle flap forms a portion of an inner cowl surface adjacent to the air-oil cooler, the nozzle flap having a leading edge and a trailing edge and being selectively movable relative to the cooling fins between an open position and a closed position, wherein actuation of the nozzle flap be