System of supporting turbine diffuser

The invention claimed is: 1. A system comprising: a circumferential lap joint between a downstream end of an outer wall of a turbine outlet and an upstream end of an outer barrel of a diffuser section, wherein the circumferential lap joint is configured to facilitate axial movement of the outer barrel relative to the outer wall within a slot between the downstream end of the outer wall and the upstream end of the outer barrel, an upstream lip of the outer barrel is disposed radially within a downstream lip of the outer wall to form the slot, and both the turbine outlet and the diffuser section are configured to receive an exhaust gas. 2. The system of claim 1 , comprising a plurality of discrete brackets coupled to the outer barrel and a frame assembly, wherein the plurality of discrete brackets is configured to axially support the outer barrel. 3. The system of claim 2 , wherein the plurality of discrete brackets comprises a plurality of support brackets, wherein each support bracket of the plurality of support brackets comprises a pin extending axially through a flange of the outer barrel, and the pin is configured to restrict circumferential movement of the outer barrel relative to the respective support bracket. 4. The system of claim 3 , wherein the plurality of discrete brackets is disposed about the outer barrel in a rotationally symmetric arrangement. 5. The system of claim 1 , wherein the system comprises: a primary flow path extending from the turbine outlet to a diffuser outlet of the diffuser section through an interior region, wherein the interior region is radially within the outer wall and the outer barrel, and the diffuser outlet is configured to direct an exhaust flow to an exhaust plenum downstream of the diffuser section; and a secondary flow path extending from the exhaust plenum to the interior region through the slot between the downstream lip of the outer wall and the upstream lip of the outer barrel, wherein the secondary flow path extends through the circumferential lap joint. 6. The system of claim 5 , comprising: a cooling passage disposed radially outside the outer wall along the downstream end of the outer wall; and a first circumferential seal coupled to the outer wall and disposed at a downstream end of the cooling passage proximate to the circumferential lap joint, wherein the first circumferential seal is configured to isolate the cooling passage from the secondary flow path. 7. The system of claim 1 , comprising a plurality of airfoils disposed within the turbine outlet, wherein the circumferential lap joint is axially disposed an attenuation length downstream of the plurality of airfoils, and the attenuation length is less than 12 inches. 8. The system of claim 1 , comprising an inner circumferential joint between a downstream end of an inner wall of the turbine outlet and an upstream end of an inner barrel of the diffuser section, wherein the inner circumferential joint comprises a plurality of discrete inner brackets configured to couple the downstream end of the inner wall to the upstream end of the inner barrel. 9. The system of claim 8 , wherein the plurality of discrete inner brackets is configured to axially support the inner barrel, and both the inner wall of the turbine outlet and the inner barrel of the diffuser section are disposed about a bearing section of a gas turbine. 10. The system of claim 1 , further comprising a gas turbine engine coupled to the turbine outlet, wherein the turbine outlet and the diffuser section are configured to receive an exhaust gas from the gas turbine engine during operation of the gas turbine engine. 11. A system comprising: a turbine outlet comprising an outer wall, an inner wall, and an airfoil disposed between the outer wall and the inner wall proximate to a downstream end of the turbine outlet, wherein the turbine outlet is configured to receive exhaust gas from a gas turbine between the outer wall and the inner wall; a diffuser section coupled to the turbine outlet, wherein the diffuser section comprises an outer barrel and an inner barrel, the diffuser section and the turbine outlet are disposed about a turbine axis, and an upstream end of the outer barrel is disposed at an attenuation length downstream of the airfoil; a primary flow path of the exhaust gas extending from the turbine outlet to a diffuser outlet of the diffuser section through an interior region, wherein the interior region is radially within the outer wall and the outer barrel; a plurality of discrete outer brackets coupled to the upstream end of the outer barrel and a frame assembly, wherein the plurality of discrete outer brackets is circumferentially spaced about the turbine axis, and the plurality of discrete outer brackets is configured to axially support the outer barrel; and a plurality of discrete inner brackets coupled to the inner barrel and the inner wall, wherein the plurality of discrete inner brackets is circumferentially spaced about the turbine axis, and the plurality of discrete inner brackets is configured to axially support the inner barrel. 12. The system of claim 11 , wherein the plurality of discrete outer brackets is configured to position the outer barrel relative to the outer wall to form a circumferential lap joint between the outer wall of the turbine outlet and the outer barrel of the diffuser section. 13. The system of claim 11 , wherein the plurality of discrete outer brackets comprises a plurality of support brackets, wherein the plurality of support brackets is a subset of the plurality of discrete outer brackets, each support bracket of the plurality of discrete outer brackets comprises a pin extending axially through a flange of the outer barrel, and the pin is configured to enable radial movement and restrict circumferential movement of the outer barrel relative to the respective support bracket. 14. The system of claim 11 , wherein the plurality of discrete inner brackets comprises a plurality of inner support brackets, wherein the plurality of discrete inner brackets is a subset of the plurality of inner support brackets, each inner support bracket of the plurality of discrete inner brackets comprises a pin extending axially through respective flanges of the inner wall and the inner barrel, and the pin is configured to enable radial movement and restrict circumferential movement of the inner barrel relative to the respective inner support bracket. 15. The system of claim 11 , comprising: a cooling passage disposed radially outside the outer wall of the turbine outlet; and a first circumferential seal coupled to the outer wall, wherein the first circumferential seal is disposed at a downstream end of the cooling passage and upstream of the diffuser section. 16. The system of claim 15 , wherein the first circumferential seal is configured to isolate the cooling passage from the exhaust gas. 17. The system of claim 11 , wherein the attenuation length is less than 12 inches. 18. The system of claim 11 , wherein the plurality of discrete inner brackets is configured to position the inner barrel relative to the inner wall to form an interface between the inner wall of the turbine outlet and the inner barrel of the diffuser section. 19. A system comprising: a turbine outlet comprising an outer wall and an inner wall, wherein the turbine outlet is configured to receive exhaust gas from a gas turbine between the outer wall and the inner wall; a diffuser section coupled to the turbine outlet, wherein the diffuser section comprises an outer barrel and an inner