Diffuser having shaped vanes

We claim: 1. A radial diffuser system comprising: a plurality of vanes positioned between a hub and a case, each of the plurality of vanes having a wedge-shape and comprising a base coupled to the hub, an outer surface adjacent to the case, a leading end arranged proximate to a radial inner edge of the hub, a trailing end arranged proximate to a radial outer edge of the hub, a first side that extends longitudinally along each of the plurality vanes, and a second side that extends longitudinally along each of the plurality of vanes opposite of the first side, wherein each of the plurality of vanes at the case has a thickness defined by a first wedge angle, the first wedge angle defined between the first side at the outer surface and the second side at the outer surface, wherein a region of each of the plurality of vanes is arranged between the base and the outer surface, the region having a thickness defined by a second wedge angle, the second wedge angle being defined between the first side at the region and the second side at the region, wherein the first wedge angle is larger than the second wedge angle, and wherein the first side of the vane at the leading end is a straight line. 2. The radial diffuser system of claim 1 , wherein a channel is defined by the first side of a first vane of the plurality of vanes, the second side of a second vane of the plurality of vanes, and a surface of the hub. 3. The radial diffuser system of claim 2 , wherein the surface of the hub is flat. 4. The radial diffuser system of claim 1 , wherein the first side of each of the plurality of vanes is arranged on a pressure side of each of the plurality of vanes and the second side of each of the plurality of vanes is arranged on a suction side of each of the plurality of vanes. 5. The radial diffuser system of claim 4 , wherein the first side and the second side each comprise an inwardly curved surface extending between the surface of the hub and the case. 6. The radial diffuser system of claim 4 , wherein the first side comprises an inwardly curved surface extending between the base and the outer surface, and wherein the second side comprises a straight surface. 7. The radial diffuser system of claim 6 , wherein the straight surface of the second side is perpendicular to a surface of the hub. 8. The radial diffuser system of claim 1 , wherein the thickness of the region between the base and the outer surface of each of the plurality of vanes varies according to a continuous function of a distance of a location within the region from the outer surface. 9. A radial diffuser comprising: one of a hub and a case having a first surface, a radial inner edge, and a radial outer edge; and a vane projecting from the first surface, the vane being wedge-shaped and comprising a leading end arranged proximate to the radial inner edge, a trailing end arranged proximate to the radial outer edge, a first side that extends longitudinally along the vane, a second side that extends longitudinally along the vane opposite of the first side, a base coupled to the first surface of the hub, an upper surface configured to receive a second surface of the other of the hub and the case, and a middle region disposed between the base and the upper surface, wherein the vane at the upper surface has a first thickness defined by a first wedge angle, the first wedge angle being defined between the first side at the upper surface and the second side at the upper surface, and wherein the vane at the middle region has a second thickness defined by a second wedge angle, the second wedge angle being defined between the first side at the middle region and the second side at the middle region, and wherein the second wedge angle of the middle region is smaller than the first wedge angle. 10. The radial diffuser of claim 9 , wherein the first side extends between the base and the upper surface of the vane, the first side having an inwardly curved surface, extending from the leading end to the trailing end. 11. The radial diffuser of claim 10 , wherein the inwardly curved surface has a curve depth which is shallowest at the leading end and deepest at the trailing end. 12. The radial diffuser of claim 9 , wherein the vane at the base has a third thickness defined by a third wedge angle which is larger than the second wedge angle. 13. The radial diffuser of claim 12 , wherein the third thickness of the vane at the base is equal to the first thickness of the vane at the upper surface. 14. The radial diffuser of claim 9 , wherein the vane comprises a rounded leading edge. 15. The radial diffuser of claim 9 , wherein the first side of the vane at the leading end is a straight line. 16. The radial diffuser of claim 9 , comprising a plurality of vanes projecting from the first surface, the plurality of vanes including the vane. 17. A method of manufacturing a radial diffuser comprising: providing a vane projecting from a first surface of one of a hub or a case, the first surface having a radial inner edge, and a radial outer edge, the vane being wedge-shaped and comprising a leading end arranged proximate to the radial inner edge, a trailing end arranged proximate to the radial outer edge, an upper surface, a base coupled to the first surface, a first side extending longitudinally along the vane, and a second side extending longitudinally along the vane opposite of the first side; and forming the vane such that the vane at the upper surface has a first thickness defined by a first wedge angle, the first wedge angle being defined between the first side of the vane at the upper surface and the second side of the vane at the upper surface, that a region of the vane arranged between the base and the upper surface of the vane has a second thickness defined by a second wedge angle, the second wedge angle being defined between the first side of the vane at the region and the second side of the vane at the region, and wherein the first wedge angle is larger than the second wedge angle. 18. The method of claim 17 , wherein the base of the vane is brazed to the first surface. 19. The method of claim 17 , wherein the vane is integrally formed from the hub. 20. The method of claim 17 , further comprising coupling the upper surface of the vane to a second surface of the other of the hub or the case.